Theory of Charges, A Study of Finitely Additive Measures

Theory of Charges

This is a volume in PURE AND APPLIED MATHEMATICS A Series of Monographs and Textbooks Editors: SAMUEL EILENBERG AND HYMAN BASS

A list of recent titles in this series appears at the end of this volume.

Theory of Charges A Study of Finitely Additive Measures

K. P. S. Bhaskara Rao Indian Statistical Institute, Calcutta, India

M. Bhaskara Rao University of Sheffield, UK

1983

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Copyright @ 1983 by ACADEMIC PRESS INC. (LONDON) LTD

All Rights Reserved No part of this book may be reproduced in any form by photostat, microfilm, or any other means without written permission from the publishers

British Library Cataloguing in Publication Data Bhaskara Rao, K.P.S. Theory of Charges-(Pure and Applied Mathematics) 1. Algebraic Topology I. Title 11. Bhaskara Rao, M. 111. Series 514' 2 QA612 ISBN 0-12-095780-9

Typeset and printed by J. W. Arrowsmith Ltd

Foreword

Many years ago, S. Bochner remarked to me that, contrary to popular mathematical opinion, finitely additive measures were more interesting, more difficult to handle, and perhaps more important than countably additive ones. At that time, I held the popular point of view, but since then I have come around to Bochner’s opinion. Apparently, many other mathematicians have also done so, as is indicated by the large number of papers listed in the bibliography of this book. I, for one, had not realized how much research had been done on finitely additive measures, at least partly because the material is scattered in isolated papers. The authors have done the mathematical community a real service by providing easy access to this research (to which they themselves have made significant contributions). This service is all the greater in that not only is the material that they cover interesting in itself, but the presentation is very clear and is enlivened with many illustrative examples. Two especially valuable features of their work are an annotated bibliography and a section of notes and comments. But perhaps the most valuable feature of the work to the working measure theorist or functional analyst lies in exhibiting clearly where countable additivity of a measure is used, and what can and what cannot be done without it. Roughly speaking, without countable additivity most of the measure theoretic examples are “counter”, but a great deal of functional analysis can be done-with more work! No one book in an area as large as this can do justice to all the material that deserves coverage, and I certainly do not blame the authors for omitting or treating too briefly some topics which I think are important. I only regret the necessity. I understand that the authors expect to write a book on finitely additive probability also, and perhaps they will include some of the topics so omitted. In any case, I look forward to seeing a continuation of the excellent work they have done in this book.

December 1982

Dorothy Maharam Stone University of Rochester Rochester, New York

This Page Intentionally Left Blank

According to S. Bochner, finitely additive measures are more interesting, and perhaps more important, than countably additive ones (see Maharam (1976)).Finitely additive measures arise quite naturally in many areas of analysis. Over the years, there has been a sustained growth of activity in finitely additive measures propelled by mathematicians and statisticians. The case for finitely additive probability is put forward strongly by Dubins and Savage (1965) in their book “How to Gamble If You Must”. They refer to de Finetti, who, in a large number of papers published as early as 1930, “has always insisted that countable additivity is not an integral part of the probability concept but is rather in the nature of a regularity hypothesis.” In fact, Dubins and Savage “view countably additive measures much as one views analytic functions-as a particularly important special case.” But not much attention is paid to finitely additive measures in text-books on Measure Theory. (Books on Functional Analysis do a bit better.) One reason could be that countably additive measures are more tractable than finitely additive ones. A need was felt to have a book on finitely additive measures which could serve as a reference book as well as a text-book. Cultivation of our interest in finitely additive measures started ten years ago. Our sustained interest in this area over the years led us to write this book. In this book we have made an attempt to present a systematic and detailed study of finitely additive measures as we understand them, filling in any gaps that we discerned. This study of finitely additive measures as a mathematical object, in many of its manifestations, is like a study that a botanist would carry on a particular plant, or that a zoologist would launch on a particular species of mammals, or that a sociologist would initiate about a certain tribe, delving deep into various facets of the subject of interest. We look at the finitely additive measure (i) as a single entity (extension, nonatomicity and purity); (ii) in relation to another of its own kind (absolute continuity and singularity); (iii) in an introspective mood (decomposition theorems); (iv) as a member of a community (Nikodym theorem and Vitali-Hahn-Saks theorem); (v) as a member of a community in motion (weak convergence); (vi) in interaction with objects of different

...

Vlll

PREFACE

kind (integration); (vii) in association with related external communities (Vp-spaces); (viii) and its behaviour in external environment (range); (ix) in its internal environment (lifting). Measure Theory (The Study of Countably Additive Measures) is an integral part of this wider study and the contrast between finite additivity and countable additivity is brought into sharp focus at various junctures in this work. This book contains a good number of examples illustrating various aspects of finitely additive measures. A special feature of this book is the Selected Annotated Bibliography provided at the end of the book listing research papers we have come across in our pursuit of finitely additive measures. We hope that this book serves practising analysts well and stimulates further research. K.P.S. Bhaskara Rao gave a series of lectures on some of the topics covered in this book at the University of Lecce (Italy) in 1980 and at the University of Naples in 1981. He acknowledges gratefully the help given by these universities in making the visits possible. We also thank the Indian Statistical Institute for rendering help in making reciprocal visits of the authors possible in connection with this work. Finally, a word of appreciation and gratitude to Surekha for her monumental patience in putting up with one of the most taxing and demanding spouses while this work was in progress. We also thank B. R. Marepalli for typing the entire manuscript.

December 1982

K.P.S. Bhaskara Rao Calcutta M. Bhaskara Rao Sheffield

Contents

Foreword Preface

vii

CHAPTER 1 1.1 1.2 1.3 1.4 1.5

PRELIMINARIES Classes of sets Set theoretical concepts Topological concepts Boolean algebras Functional analytic concepts

1 1 13 15 18 23

CHAPTER 2 2.1 2.2 2.3 2.4 2.5 2.6

CHARGES Basic concepts The space of all bounded charges, b a ( Q 9 ) Measures The space of all bounded measures, ca(R, 9) Jordan Decomposition theorem Hahn Decomposition theorem

35 35 43 47 50 52 56

CHAPTER 3 3.1 3.2 3.3 3.4 3.5 3.6

EXTENSIONS OF CHARGES Real valued set functions and induced functionals Real partial charges and their extensions Extension procedure of Eos and Marczewski Extension of partial charges in the general case Miscellaneous extensions Common extensions

58 58 64 70 76 78 82

CHAPTER 4 4.1 4.2 4.3 4.4 4.5 4.6 4.7

INTEGRATION Total variation and outer charges Null sets and null functions Hazy convergence D-integral S-integral L,- spaces b a ( O , 9 ) as a dual space

85 85 87 92 96 115 121 133

CHAPTER 5 5.1 5.2 5.3 5.4

NONATOMIC CHARGES Basic concepts Sobczyk-Hammer Decomposition theorem Existence of nonatomic charges Denseness

141 141 144 150 156

V

CONTENTS

X

CHAPTER 6 6.1 6.2 6.3

ABSOLUTE CONTINUITY Absolute continuity and singularity Lebesgue Decomposition theorem Radon-Nikodym theorem

159 159 166 169

CHAPTER 7 7.1 7.2 7.3 7.4 7.5

V,,-SPACES L,- spaces-An overview V,- spaces Duals of V,- spaces Strong Convergence Weak Convergence

178 178 185 193 197 200

CHAPTER 8 NIKODYM THEOREM, WEAK CONVERGENCE AND VITALI-HAHNSAKS THEOREM 8.1 Nikodym and Vitali-Hahn-Saks theorems in the classical case 8.2 Examples 8.3 Phillips' lemma 8.4 Nikodym theorem 8.5 Norm bounded sets in the presence of uniform absolute continuity 8.6 A decomposition theorem 8.7 Weak convergence 8.8 Vitali-Hahn-Saks theorem

203 204 205 206 209 213 216 218 226

CHAPTER 9 THE DUAL OF b a ( 4 9 ) AND THE REFINEMENT 23 1 INTEGRAL 23 1 9.1 Refinement integral 234 9.2 The dual of ba(R, 9) CHAPTER 10 10.1 10.2 10.3 10.4 10.5

PURE CHARGES Definitions and properties A decomposition theorem Pure charges on cr- fields Examples Pure charges on Boolean algebras

240 240 24 1 243 244 246

CHAPTER 11 11.1 11.2 11.3 11.4 11.5

RANGES OF CHARGES Ranges of bounded charges on fields Ranges of charges on cr-fields Cardinalities of ranges of charges Charges with closed range Charges whose ranges are neither Lebesgue measurable nor have the property of Bake

249 249 252 256 257 264

CHAPTER 12 ON LIFI'ING Appendix 1: Notes and Comments Appendix 2: Selected Annotated Bibliography Appendix 3: Some Set Theoretic Nomenclature Index of Symbols and Function Spaces Subject Index

268 272 282 305 306 309

CHAPTER 1

Preliminaries

The only prerequisite that is needed for understanding a substantial part of this book is a knowledge of Real Analysis, Set Theory and General Topology at a rudimentary level. The purpose of this chapter is to collect, in succinct form, various basic notions and results that are needed in this book. Section 1.1 presents various classes of sets and their properties. Section 1.2 briefly touches o n some notions from Set Theory. Section 1.3 makes a sojourn with General Topology. Section 1.4 briefly dwells on Boolean Algebras. Finally, Section 1.5 presents vector lattices in some detail adequate for our needs. A word of advice; before entering the terrain of finitely additive measures, the reader is urged to ensure a good degree of familiarity with the concepts presented in this chapter.

1.1 CLASSES OF SETS Various types of classes of sets are presented in this section. The most important concept is the field of subsets of a set. This collection is, usually, the domain of definition for finitely additive measures. Throughout this book, R is always understood to be a non-empty set. The set theoretic operations we use are standard. For the reader’s convenience, a list is appended at the end of this book.

1.1.1 Definitions. Let fl be a set and 8 a collection of subsets of R. (1). 9is said to be a lattice on R if the following conditions are satisfied. (i). A, B E 9 3 A u B E g. (ii). A , B E ~ ~ A ~ B E ~ . (2). $is said to be a semi-ring on fl if the following conditions are satisfied. (i). 0 E 9. (ii). A , B c 9 3 A n B € $ . (iii). If A, B E $ and A c B , then there exists a finite number Ao, A1,. . . ,A, of sets in $such that A = A o c A 1 c A z c -* - cA, = B and Ai - A ~ - I~ 8 f o i r= 1 , 2 , . . . ,n.

2

THEORY OF CHARGES

(3). 9is said to be a semi-field on R if 9 is a semi-ring and R E 9. (4). 9is said to be a ring on R if the following conditions are satisfied. (i). 0 EF. (ii). A , B E ~ ~ A u B E ~ . (iii). A, B E 9+A- B E 9. (5). 9is said to be a field on R if 9is a ring and R E 9. ( 6 ) . 9 is said to be an additive-class on R if the following conditions are satisfied. (i). 0 E 9. (ii). A, B E 9and A nB = 0+ A u B E 9. (iii). A E 41I$A' E 9. (7). 9is said to be a cr-ring on R if the following conditions are satisfied. (i). 0 €9. (ii). {A,,; n h 1)c 9 3 U n zA,, l E 9. (iii). A, B E 9 3 A - B E 9. (8). 9 is said to be a cr-field on R if 9is a cr-ring on R and R E 9. (9). 9 is said to be a a-class on R if the following conditions are satisfied. (i). 0 €9. (ii). If A,, n 2 1 is a sequence of pairwise disjoint sets in 9, then

U n z l A n E 9. (iii). A E ~ + A ~ E ~ , One could form a comprehensive picture of the interrelations between various types of classes introduced above. We shall not go into details. We present some important ones in the following.

1.1.2 Remarks. (1). A lattice of sets need not be a semi-ring. (2). A semi-ring need not be a lattice. (3). Every ring is a semi-ring. (4). Every ring is a lattice. ( 5 ) . Every field is a ring. (6). Every field is a semi-field. (7). Every field is an additive-class. (8). Every a-field is a field. (9). Every cr-field is a cr-ring. (10). Every a-field is a a-class.

The above statements can be easily verified. The converse of any of the implications in (3) to (10)does not hold. Examples can easily be constructed. A sample of examples to illustrate some of the definitions is presented here. Many more are to come later.

1.

PRELIMINARIES

3

1.1.3 Examples. (1). Let R be any infinite set. A set A c R is said to be cofinite if A' is a finite subset of R. Let 9 be the collection of all finite and cofinite subsets of R. Then 9is a field on R, but not a cr-field on a. (2). Let R = [0, 1) and %' ={[a,6 ) ;0 5 a Ib I1). Then %' is a semi-field on R. ( 3 ) . Let R = [0,1) and 9= [ai,bi);[ai,b i ) n [aj,b j )= 0 for all i # j , 0 5 ai Ibi I1 for all i, n 2 1). Then 9 is a field on R. 9 is precisely the collection of all those subsets of R each of which is a finite disjoint union of sets from %' of (2) above. It will follow from Theorem 1.1.9(2) that 9 is precisely the smallest field on R containing %'. (4).Let P(n)denote the class of all subsets of R. (P(R) is called the power set of 0.)Then S(R)is an example of each type of class presented in Definition 1.1.1. P(R) is also called discrete field or discrete cr-field on a.

{uY=l

In the following, we give salient features of some important types of classes presented in Definition 1.1.1. These are not hard to discern.

1.1.4 Properties. (1). If 9is a ring on R, then Ai and Ai E 9 f o r any finite number AI,AZ,, . . ,A, of sets in 9, i.e. 9is closed under finite unions and finite intersections. (2). If 9is a ring on R, then 9is closed under symmetric differences, i.e. A AB = (A - B) u (B -A) E 9whenever A, B E 9. ( 3 ) . If 9 is a semi-ring on R and is closed under finite disjoint unions, then 9is a ring on R. (4).If 9is an additive-class on R, then 9is closed under proper differences, i.e. A - B E 9whenever A, BE^ and B c A. ( 5 ) . If 9 is an additive-class on R and is closed under finite intersections or differences, then 9is a field on R. (6). If 9 is a a-ring on R, then 9 is closed under countable intersections, A, E 9 whenever A,, n 2 1 is a sequence of sets in 9. i.e. (7). If 9 is a cr-class on R and is closed under finite intersections or differences, then 9is a c-field on R.

u:='=,ny='=,

n,,,

A given collection %? of subsets of a set R may not be of a particular type P listed in Definition 1.1.1. It is natural to enquire about the existence of a smallest collection 9 of subsets of l2 of the type P containing %'.The following results are designed to answer this query. 1.1.5 Lemma. Let R be any set and P be any of the types listed in Definition 1.1.1 with the exception of P being a semi-ring or a semi-field. Let ga, a Er be a family of collections of subsets of R such that each ga is of type P. Then gais of type P.

naEr

4

THEORY OF CHARGES

Proof. The proof easily follows from the definitions of each type.

0

1.1.6 Remark. The following example explains why we have made exceptions of certain types of classes of sets in the above lemma. Let Q = {1,2,3,41, 9 1

={0, (11, (21, {I3219 (3,413 a1

and 9 2=

10, (11, {2,3,4), 0).

91 and g2are semi-fields on R but % = 91 n92 = {0, {l),R} is not a semi-field on R. 1.1.7 Theorem. Let R be any set and P be any of the types listed in Definition 1.1.1 with the exception of P being a semi-ring or a semi-field. Let % be a collection of subsets of R. Then there exists a smallest collection $of subsets of R of type P containing %. Proof. Let 9=, a E r be the family of all collections of subsets of R each of which is of type P and contains %. r f 0 since 9 ( R ) is of type P and contains %. Then, by Lemma 1.1.5,9 = Paris of type P and contains %. It is not hard to see that 9is the desired collection of sets. 0

nar.r

In the above, % is called a generator of 9with respect to the type P or, simply a generator of 9 if P is understood.

1.1.8 Remark. Let R={1, 2,3,4) and % ={0, {l), R}. Then there is no smallest semi-field 9 o n R containing %. See Remark 1.1.6. In some special cases, we can explicitly construct the smallest collection 9of subsets of R of a given type containing a given collection % of subsets of R. The following theorem gives some examples of such cases.

1.1.9 Theorem. Let R be any set. (1). Let % be a lattice on R and 0 E %.Let 9 = { F - E ; E, F E %and E c F ) . Then 9 is the smallest semi-ring on R containing %. (2). Let % be a semi-ring on R and 9= {ul=l C i C1, ; CZ,. . . , C, are pairwise disjoint sets in % and n ? 1). Then 9 ' i s the smallest ring on R containing %. (3). Let % be a semi-field on R and 9 = Ci; CI, C2, . . . , C, are pairwise disjoint sets in % and n 2 1). Then 9 is the smallest field on SZ containing %. (4). Let % be a ring on R. Let %I ={A c a;A'E %}. Then 9 = % v %I is the smallest field on R containing %. ( 5 ) . Let % be a u-ring on R. Let %I ={A c R; A' E %}. Then 9= % v %I is the smallest u-field on R containing %.

{uy=l

1. PRELIMINARIES

5

Proof. (1). Let F1 -El and FZ-Ez E 9, where El, F1, E2,F2 E %, EI c F1 and El c F2. Then (F1-El) n(F2-Ez) = (FInFz)- (EluE2)n(F1nF2)E 9. So, 9 is closed under finite intersections. Let F1 -El, F2-Ez E 9 and F1-El c F2- E2, where El, F1, E2, F2E %, El c F1 and EZc Fz. Let C = F1 -El c C c Fz -E2, C- (F1-El) E 9 (F1nF2)- (FInE2). Then C E 9, and (FZ-E2)-C€ 9. Hence 9 is a semi-ring on R. Since 0 E %?, %? ~ 9 . It is not hard to see that 9is indeed the smallest semi-ring on Cl containing %. (2). From the definition of 9, it is clear that 9 is closed under finite disjoint unions. We show that 9is closed under finite intersections. let U:=I Ci E 9 and D j E 9, where C1, C2, . . . , Cm are pairwise disjoint sets in % and D1, D2, * ,D, are pairwise disjoint sets in %. Then

u,”=l

since Ci n D , i = 1 ,2 , . . . , m and j = 1 ,2 , . . . , n are pairwise disjoint sets in %’. Now, we show that F is closed under differences. Suppose E, F E % and E c F . Then there exist Eo,El,. .. , E n in % such that E = E ~ ~ E ~ ~ . . . ~ E n = F a n d E i - E for i - 1e v€e% r y i = l , 2 , . . . , n. So, FE= (Ei -EiPl)E 9, since Ei -Ei-l’s are pairwise disjoint. Let Ci Dj be any two sets in 9, where C1, Cz, . . . , C, are pairwise and disjoint sets from % and D1, Dz, . . . ,D, are pairwise disjoint sets from %. Note that

uYzl

ur=~ uy=l

n

=

m

u n (Dj- (Ci nDj)).

j=1 i=l

From what we have proved above, D j - (Ci n Dj) E 9for every i and j . Since 9is closed under finite intersections, (Dj - (CinDj))E 9 for every j . Since 9is closed under finite disjoint unions,

nk

u n(Dj-(CinDj))E9. n

m

j-1

i=]

If we show that 9 is closed under finite unions, it would imply that 9 is aringonn. LetA,BEF.ThenAuB=Au(B-A). SinceB-AE9and A and B -A are disjoint, it follows that A u B E 9. It is obvious that % c 9. It is not hard to see that 9is indeed the smallest ring on R containing %. (3). This is similar to (2). (4).We show that 9 is a field on R. It is obvious that 9 is closed under complementation. Let E, F E 9.Case (i). E, F E %. Then E u F E % c F.

6

THEORY OF CHARGES

Case (ii). E E % and F E % ~Then . E u F E % : , . For, (EuF)'=E'nF'= F - E E %. Case (iii). E E %I and F E%. This case is similar to Case (ii). Case (iv). E , F E % l . Then E u F E Y 1 . For, (EuF)"=E'nF'E%. In any Thus 9is a field on R containing %. It is obvious case, we have E u F E 9. that 9is the smallest field on R containing %. ( 5 ) . This can be proved as in (4). 0 Next, we describe a constructive procedure for obtaining the smallest field 9 on R containing a given class % of subsets of R in a finite number of steps. First, we introduce a special notation.

1.1.10 Notation. For any subset A of R, let A' = A and A'

= A'.

1.1.11 Theorem. Let % be any class of subsets of a set 0. Form the following classes of sets successively. q1= ( 0 ,R}u % u{Ac R; A'E %}.

W2= The collection of all subsets of R each of which is a finite intersection of sets from g1.

=(AAi;

I.

for i = 1 , 2 , . . . ,n and n 21

i=l

q3= The collection of all subsets of R each of which is a finite disjoint union of sets from %2. =

{ 6Bj; Bj€%2for all j , Bi n B j

= 0 for all

i Z j a n d m rl

j=1

I.

Then V3 is the smallest field on R containing %, Proof. We note the following obvious facts. (i). % C % ~ C % : Z C % ~ . (ii). 0 E Z3. (iii). V1 is closed under complementation, i.e. if A E q1,then A'E V1.(iv). "2 is closed under finite intersections. (v). %3 is closed under finite disjoint unions. (vi). If %3 is a field on R, then it is indeed the smallest field on 0 containing %. We show that g3is a field on R. This is carried out in the following steps. Step 1. Note that if a collection 9 of subsets of a set fl is closed under complementation and finite intersections, then 9 i s a field on R. (If A, B E 9, then A u B = (A"nB")' E 9.) Step 2. It is clear that Z3 is closed under finite intersections in view of the fact that Z2is closed under finite intersections. Step 3. Let A E Z2.We claim that A'E q3.We can write A = fy=l Ai for some A1,A2,. . . ,A, in '%I. Note that A' = A? nA > n* nA:n, where the union is taken over all S1,S2,. . . ,a, in (0,l) with the exception that

u

--

1, PRELIMINARIES

7

(S1,S2,..., & ) = ( l , l , ..., 1). Each A ? ' n A 9 n . - . n A > belongs to Wz and these sets are pairwise disjoint. So, A"EW3. Step 4. As a final step, let B E W3. Then B = u y = l Bi for some pairwise B:. Then each B:E q3, disjoint sets B1, B2, . . . ,B, in Wz.Then B" = by Step 3. By Step 2, B'E W3. This completes the proof. 0

ny=l

We obtain some important consequences of this result.

1.1.12 Corollary. Let W be any class of subsets of a set R and 9 the smallest field on R containing %. Then the following statements are true. (1). A E9 if and only if there exist sets A,, j = 1,2, . . . ,ni and i = 1, 2, . . . ,m such that each A, or AGE%? and

u n A,. m

A=

i=l j = l

(2). A E $if and only if there exist sets Bii,j such that each Bii or B;E %? and

. . . ,kiand i = 1 ,2 , . . . ,n,

k,

n u Bib n

A=

= 1 ,2 ,

j=l

j=1

Proof. (1). This follows from Theorem 1.1.11. (2). This follows from (1) and the distributive laws of the operations u and n.

1.1.13 Corollary. Let 9 be a field of subsets of a set R and A c a.Then the smallest field 9 1 on R containing 9and A is given by 9 1 = {(B

nA) u (Bz n A"); B 1, B2 E s}.

Proof. This follows from Corollary 1.1.12(1). (One can also show that is a field on R directly.)

9 1

1.1.14 Corollary. Let % be any countable collection of subsets of a set R. Then the smallest field 9on R containing %? is also countable. Proof. This follows from Theorem 1.1.11. (Note that each q iconstructed in the proof of Theorem 1.1.11 is countable.) 0 1.1.15 Remark. Given a class %? of subsets of a set R, there is no simple way of constructing the smallest cr-field on R containing Y.The collection of all countable unions of sets each of which either belongs to % or its complement belongs to % need not be a cr-field on 0. Now, we introduce the notion of an atom of a field.

1.1.16 Definitions. Let 9 be a field of subsets of a set R.

8

THEORY OF CHARGES

(1). A set A in 9 is said to be an atom of 9 if the following conditions are satisfied. (i). A f 0 . (ii). B E $ , B c A J B = 0 or B = A . (2). 9 is said to be atomic if every non-empty set in 9 contains an atom of 9. (3). 9 is said to be nonatomic if 9has no atoms. An atom A of 9 is, intuitively, a minimal non-empty element of 9. If A and B are atoms of 9, then either A = B or A n B = 0. The following remarks give some more information about these notions.

1.1.17 Remarks. (1). If R is the union of all atoms of 9, then 9 is atomic. But the converse is not true. As an example, let R = {1,2,3, . . . , CO} and 9 be the collection of all finite subsets of {1,2,3, . . .} and their complements. Then 9is atomic. But the union of all atoms of 9 = {1,2,3, . . .} # R. (2). If 9 is a finite field on R, then 9 is atomic. For each w in R, let A, =n,.,,,A. Then A, is an atom of 9 containing w . (3). For any set R, P(R) is atomic. (4). The field given in Example 1.1.3(3) is nonatomic. If %' is a finite collection of subsets of a set R, then the smallest field 9 on R containing W can be described in a simple way. The following proposition amplifies this point.

1.1.18 Proposition. (1). If % = {Al, Az, . . . , A,} is a finite partition of R, i.e. Ai n A j = 0 for Ai = R and A, # 0 for every i, then the smallest fieZd 9 on all i # j , R containing W is the collection of all possible unions of sets from W. The atoms of 9 are precisely A1, Az, . . . , A,,. (2). If W ={A1, AZ,. . . , A,} is any finite collection of subsets of a set R, then the smallest field 9 on R containing %' is the collection of all possible unions of sets from g1= {AY1n Ag'n * n A:-; S1,Sz, . . . ,S,, E (0, l}}.The atoms of 9are precisely the non-empty sets in %'I. (3). I f 9= {B1,Bz, . . . , B,,,} is a finite field on a set R, then the atoms of S u r e the non-empty sets from

uy=,

-

{BY'nBgZn...nB6,,;S1,S2 , . . . , S,E{O,l}}. (4). If 9 is a finite field on R, then the number of sets in 9 is 2k for some kzl.

The above statements are easy to check and the details are left to the reader.

1.

PRELIMINARIES

9

Now, we collate the two notions, an additive-class and a field, in relation to generators. The following results are in this direction.

1.1.19 Theorem. Let % be a class of subsets of a set 0, gothe smallest additive-class on R containing %' and 9 1 the smallest field on R containing %. Suppose V has one of the following properties. (i). A, B E % A nB E 9 0 . (ii). A, B E% + A - B E 90. Then 90= 91.

+

Proof. Since Sois the smallest additive-class containing % and S1is an additive-class containing %, it follows that g o c $1. If we show that 90 is a field, it would then follow that g1c goand hence go= gl. For this, it suffices to show that gois closed under finite intersections or differences. See Property 1.1.4(5). Suppose (i) holds. For each A in So,define . F A = {B E 9 0 ;A n B E go}. We show that is an additive-class. Clearly, @ € % A . If B E ~ A then , A n B c = A - B = A - ( A n B ) E s o as gois closed under proper differences. See Property 1.1.4(4).So, B'E $A. It is easy to check that g A is closed under finite disjoint unions. Thus F A is an additiveclass contained in 9-0. If A E %, then % c g A , by (if. Therefore, g A = g o . Now, if A E So,even then % c 9 A . For, if C E %, then .?Fc = 9 0 and SO, A nCE or C E F A . Consequently, FA = $0 for any A in F 0 . This implies that gois closed under finite intersections. One can show that the properties (i) and (ii) are equivalent using Property 1.1.4(4). This completes the proof. 0 An easy consequence of the above result is the following observation. If %' is a class of subsets of a set R closed under finite intersections or differences, then the smallest additive-class on R containing %? and the smallest field on R containing %? are identical. The following results are in the spirit of Theorem 1.1.19but in the setting of a-classes and a-fields.

1.1.20 Theorem. Let % be a class of subsets of a set R and gothe smallest a-class on R containing %. Suppose V has one of the following properties (which are equivalent anyway). (i). A, B E % + A n B E g o . (ii). A , B E V + A - B E ~ O . 0 Let glbe the smallest a-field on R containing V.Then 9 0 = F1. 1.1.21 Corollary. Let %' be a collection of subsets of a set R closed under finite intersections or differences. Let FO be the smallest a-class on R contain ing %' and gl the smallest a-field on R containing V.Then g o = $1. 0

10

THEORY OF CHARGES

A proof of Theorem 1.1.20 can be given by a slight modification of the proof of Theorem 1.1.19. Corollary 1.1.21 follows easily from Theorem 1.1.20. Next, we introduce two very useful notions, namely “Ideals and Filters” which are complementary to each other.

1.1.22 Definitions. Let 9be a field of subsets of a set a. (1). 4 c 9is said to be an ideal in 9 if the following conditions are satisfied. (i). R g 4 . (ii). A , B E ~ + A U B E $ . (iii). A € $ , B c 9 , B c A J B e 4 . An ideal 4 in 9 is said to be a maximal ideal in 9 if there is no ideal in 9properly containing 4. (2). 8;c 9is said to be afilter in 9if the following conditions are satisfied. (i). 0 g8;. (ii). A, Bc$+AnBEB;. (iii). A€$, BE^, A ~ B J B E ~ ; . A filter 8; in 9is said to be a maximal filter in 9 if there is no filter in 9 properly containing 8;.

1.1.23 Remarks. The following statements follow from the above definitions. (1). If 4 is an ideal in 9, then 8;={A E 9; A‘ E 4)is a filter in 9. If 4 is then the filter 8; defined above is a maximal filter a maximal ideal in 9, in 9. (2). If R = {1,2,3, . . .} and 4={A c R; A is finite}, then 4 is an ideal in 9= s ( R ) . 4 is not a maximal ideal in 9. (3). If %’ c 9 has the property that Ci# R for any finite number C1, Cz, . . . ,C, of sets in %’, then there exists a smallest ideal 4 in 9 containing %’.In fact, 4 is given by

uy=l

6 Ci for some C1, C2,. . . ,C, in %‘I. (4). If %’ c 9 has the property that n;=, C i# 0 for any finite number A E ~A ;c

i=l

C1, C2,. . . ,C, of sets in %’,then there exists a smallest filter 8; in 9 containing %’.In fact, 8; is given by

8;={A€$;

h Ci = A for some C1, C2,. . . ,C, in

i=l

%‘I.

(5). Let 9 be an ideal in 9 and A E 9. Suppose A u B # R for any B in 4. Then 9 1

={CE 9; C c A u B for some B in 4 )

1. PRELIMINARIES

11

is the smallest ideal in 9containing 4 and A. We call Y1the ideal generated by 4 and A. (6). Let 9 be a filter in 9 and D E 9. Suppose D nB # 0 for every B in 9.Then

91={CE9;DnBcCforsomeBin$} is the smallest filter containing 9 and D. We call the filter generated b y 2 and D. (7). An ideal 4 in 9is a maximal ideal in 9if and only if for every A in 9either A or A' E 4. (This follows from (5).) (8). A filter 9 in 9 is a maximal filter in 9 if and only if for every A in 9either A or A'€$. (This follows from (6).) (9). If 9l and $2 are two distinct maximal filters in 9, then there exists A in 9such that A ~9~ and A ' E ~ ~ . We define limit supremum and limit infimum of a sequence of sets and give some properties of these notions.

1.1.24 Definitions. Let A,, n 2 1 be a sequence of subsets of a set R. Define lim sup A,, =

n u Ak

nzl kzn

n+m

and lim inf A, n-m

=

u n Ak.

n z l kzn

1.1.25 Properties. (1). lirn sup,,oo A, = {w ; w E A, for infinitely many n's}. (2). lim inf,,, A, = {w ;w E A, for all but a finite number of n's}. (3). lim inf,,m A, c lim sup,,m A,. (4). (lim A,)" = lim inf,,m A:. (5). (lim inf,,m A,)" = lim A:. Now, we introduce some operations in the setting of real valued functions defined on a set. Let f and g be two real valued functions defined on a set R. f v g, f A g, f- and If1 are functions on CR defined by

a

(fv d ( w ) = max Mw),g(o)},

wE

( f A g>(w>= min {f(o>, g(w)},

w E Q,

f + = f vo,

f- = (-f)v 0

12

THEORY OF CHARGES

and

Iflb)= If(w>l,

CIJ

E a.

We give some identities involving these operations which actually stem from the corresponding properties of real numbers.

1.1.26 Identities. (1). f = f +-f-.

.

y-.

(2). If1 =f+ (3). f v g = d f + g + I f - d . (4). f g = 3 f + g - If-gl). ( 5 ) . f + g = (f v g>+ ( f g). ( 6 ) . If-g,' = (fv g ) - (f. g). (7). fg =4"f+g)2-(f-g)21. (8). I f l = f + v f - = f V (-f). (9). IIfl-lgll~If+gl~lJfl+lgl. (10). I(fl V gi) - (fz v g2)I 5 If1 -fzl+ lgl - gzI for any real valued functions f l , fz, g1, gz on a. (11). 1(f1 A 81) -(fz A gz)]5 If1 + Igl -gzI for any real valued functions f l , fz, g1, g2 on a. (12). - I f l - l ~ l ~ f ~ g ~ f v g ~ l f l + I g l .

-fzl

Finally, we end this section with some notes on measurable functions.

1.1.27 Definitions. (1). The BoreZ a-field on the real line R is defined to be the smallest a-field on R containing all intervals. (2). Let R be a set and % a c+-field on R. A real valued function f on R is said to be measurable with respect to % if f-'(B) = {w E R; f ( w) E B} E % for every Bore1 subset B of R. ( 3 ) . For any subset A of R, the indicator function I A of A is a map from to R given by I A ( w )= 1, if w E A, =0, if w €AC.

1.1.28 Properties, Let '% be a a-field of subsets of a set R. Then the following statements are true. (1). For A c R, la is measurable with respect to % if and only if A € % . (2). A real valued function f on R is measurable with respect to % if and only if f-'{[k, CO)} E % for every -a< k < a. ( 3 ) . If f , g are measurable functions with respect to 3 and c, d are real numbers, then cf + dg, I f l , fg, f2, f v g, f A g, f' and f- are all measurable functions with respect to %. (4). A real valued function f on R is a measurable function with respect to '% if and only if there exists a sequence fa, n I1 of functions on R such

1. PRELIMINARIES that f ( w ) = limn+mfn(oJ)for every w in

a, where each fn

13 is of the form

for some real numbers cnl, c n z , . . . ,C n k , and for some sets Anl,An2,.. . , A,k, from 3 .

1.2 SET THEORETICAL CONCEPTS

In this section, we present, in a concise form, some of the set theoretical notions we have used in this book. One of the basic concepts in set theory is the notion of a relation on a set X. A relation on X is any subset Z of X x X, where X x X is the Cartesian product of X with itself, i.e. X x X = {(x, y ) ; x, y E X}. A relation Z c X X X is said to be reflexive if (x,x) E Z for every x in X, symmetric if (x, y ) E Z whenever (y, x) E Z, antisymmetric if (x, y ) , ( y , x) E Z only when x = y, transitive if (x,z ) E Z whenever (x, y ) and (y, z ) E Z for some y in X. A partial order on a set X is any relation Z which is reflexive, antisymmetric and transitive. We usually denote a partial order Z c X X X by I, i.e. for x, y in X, x Iy if and only if (x,y ) E Z . In terms of the notation I, the axioms of a partial order can be restated as follows. (i). x Ix for every x in X. (ii). x Iy and y 5 x j x = y (antisymmetry). (iii). x 5 y and y Iz 3 x 12 (transitivity). The pair (X, I) is called a partially ordered set. A partial order Ion a set X is said to be a linear order on X if x I y or y 5 x for any x, y in X. In this case, we call (X, I) a linearly ordered set. Let (X, 5)be a partially ordered set. A subset C of X is called a chain in X if the partial order Irestricted to C is a linear order on C. A partial order Ion a set X is said to be a we@-ordering on X, if for every non-empty subset A of X, there exists an element a in A such that a IX for all x in A, i.e. a is the smallest element in A. In this case, the pair (X, I) is called a well-ordered set. A relation Z c X x X is said to direct X if the following are satisfied. (i). (x,x) E Z for every x in X (reflexivity). (ii). (x,z ) E Z whenever (x, y ) and (y, z ) E Z for some y in X (transitivity). (iii). For every x, y in X, there exists z in X such that ( z , x ) E Z and ( z , y ) Z.~ The relation Z c X x X satisfying (i), (ii) and (iii) above is usually denoted by L, i.e. x 2 y if and only if (x,y ) E Z. In terms of this notation I, the above three conditions can be restated as follows. The relation 2 on X is said to direct X if the following are satisfied. (i). x zx for every x in X. (ii). x L Z whenever x 2 y and y L Z for some y in X. (iii). For every x, y in X, there exists z in X such that z Ix and z L y. The pair (X, 2 ) is called a directed set.

14

THEORY OF CHARGES

A relation Z c X x X is said to be an equivalence relation if the following are satisfied. (i). ( x , x ) ~ Zfor every x in X (reflexivity). (ii). (x, Y ) E Z whenever ( y , x ) E Z (symmetry). (iii). (x, 2 ) E Z whenever (x, y ) and (y, z ) E Z for some y in X (transitivity). An equivalence relation on X is usually denoted by -. In terms of the notation -, the above conditions can be rephrased as follows. (i). x -x for every x in X. (ii). x - y if y -x. (iii). x - 2 whenever x - y and y -2. If is an equivalence relation on X, let [XI denote the equivalence class in X containing x €or any x in X, i.e. [ x ] = { y ~ X ; y - x } .For x , y in X, [ x ] = [ y ] or [ x ] n [ y ] = 0 .Under the on X, X thus can be written as the union of all its equivalence relation equivalence classes. On some occasions, we use cardinals and ordinals. The reader is advised to refer to Kamke (1950) or any other book on Set Theory. Transfinite induction is often used in inductive definitions, inductive constructions and in proofs. Let (X, I) be a well-ordered set. Let a. be the smallest element in X. For each x in X, let A(x) be a proposition.

-

-

1.2.1 Principle of Transfinite Induction. If ( i )A(ao)is valid, and (ii)for any a in X, A ( a ) is valid whenever A(x) is valid for every x < a (i.e. x Ia and x f a ) hold, then A(x)is valid for every x in X. The above principle is also adopted for inductive definitions and inductive constructions. We will be using Zorn's lemma in this book to exhibit objects with specified properties. This lemma which is equivalent to the Axiom of Choice is stated below.

1.2.2 Zorn's Lemma. Let (X, I) be a partially ordered set in which every chain C has an upper bound, i.e. there exists a in X such that x 5 a for every x in C. Then X has a maximal element ao, i.e. if a l E X and a o l a l , then al = ao. 1.2.3 A n Application of Zorn's Lemma. Let 9 be a field of subsets of a Then there exists a maximal ideal 4" in 9 set R and 9 an ideal in 9. containing 9. Existence of 9" can be established by Zorn's lemma as 92 follows. Let X be the collection of all ideals in 9containing 9.For 91, in X, say 9l ~9~if 9l~ 95 is~a partial . order on X. Let {,aa;CY E r}be E X and is an upper bound of the chain a chain in X. Then UaEr9a {9a; CY EF). Consequently, there exists a maximal element 9" in X. Similarly, if 3 is a filter in S, one can show that there exists a maximal filter 8;* in 9containing 3, using Zorn's lemma. Finally, we end this section with an important example of a directed set. Let 9be a field of subsets of a set a. A finite partition of 0 in 9is a finite

1. PRELIMINARIES

15

family P ={El, E2, . . . , Em}of pairwise disjoint sets in 9 whose union is a. Let B denote the collection of all finite partitions of R in 9. For P1, say PI L PZif every set in P1 is contained in some set of P2. Another PZin 9, expression that is commonly used in this case is that PI is a refinement of Pz. We claim that the relation 2 on B directs 8.It is obvious that P Z P for every P in 9. If P 1 2 P z and P22P3, then it is clear that P l z P 3 . If PI ={El, Ez, . . ,Em}E 9 and Pz = {F1,Fz, . . . ,F,} E 9, then P = {EinFj; 15 i Im, 15 j In }E 9 and P 2 P1, P L Pz. Hence the relation 2 directs 9. In other words, (9,2 ) is a directed set. If F E ~let, PFdenote the collection of all finite partitions of F in 9.Under the same relation 2 as above, (PF, 1)is also a directed set.

.

1.3 TOPOLOGICAL CONCEPTS In this section, we briefly review some of the topological concepts needed in the subsequent chapters. For any other unexplained terminology in the text which slipped inadvertently from our compilation here, the reader is advised to refer to Kelley (1955). A topological space is a pair (X, Y), where X is a set and Y is a collection of subsets of X closed under unions and finite intersections and contains 0 and X. Members of Y are called open sets and the complements of open sets are called closed sets. For any set A c X , the closure of A is defined to be the set {C; C closed, A c C } and is denoted by A. A is the smallest closed set containing A. Interior of A is defined to be the set {V; V open, V c A} and is denoted by A". A" is the largest open set contained in A. A subset A of X is said to be a G6-set if A is a countable intersection of open sets. A subset B of X is said to be an F,-set if B is a countable union of closed sets. A point x in X is an accumulation point of a subset A of X if (A-{x}) nU # 0 for every open set U containing x. A point x in A c X is an isolated point of A if there exists an open set U containing x such that A n U = {x}. is any function from a directed set A net in a topological space (X, 9) (D, L) into X. Nets are usually denoted by x,, a E D . A net x,, a E D is said to converge to an element x in X if given any open set V containing x, there exists a0 in D such that x, E V whenever a z a0.A subset A of X is closed if and only if x E A whenever there is a net in A converging to x. Let (D, L) be a directed set. Suppose for every a in D, there is a /3, in D such that Pa 2 a. If x,, a E D is a net in X, then xOa,a E D is called a subnet of x,, a E D. If a net x,, a E D is convergent in X, then every subnet of x,, a E D is also convergent and converges to the same limit.

n

u

16

THEORY OF CHARGES

A topological space (X, Y) is said to be a Hausdorf topological space if for every distinct x, y in X, there exist open sets V1 and V2 such that x E V1, y E V2 and V1 nV2 = 0. An open cover of X is any family of open is said to be compact if sets whose union is X. A topological space (X, 9) every open cover of X admits a finite subcover of X. A topological space (X, Y) is compact if and only if every net in X admits a convergent subnet in X. Equivalently, (X, Y) is compact if and only if for every collection of closed sets {A,; a! E r}with finite intersection property, i.e. A, # 0 for every finite subset rlof r, A, # 0. The notion of compactness of a subset A of X can also be introduced in the same way as above for X. If A is a closed subset of X and X is compact, then A is compact. If (X, 3)is any Hausdorff topological space, then any compact subset of X is closed. A subset A of X is said to be clopen if A is open as well as closed. A topological space'(X, Y) is said to be totally disconnected if the family of all clopen subsets of X forms a base for the topology of X, i.e. every open set is a union of clopen sets. Let X be any set. Let 8 be a family of subsets of X closed under finite intersections and containing X. Then there is a smallest topology on X for which 8 is a base. This smallest topology is precisely the collection of all unions of sets from 8. Let (X, 9) be a topological space. A real valued function f on X is said to be continuous if f-l(U) E T for every open subset U of the real line R, i.e. U is a union of open intervals. f is continuous if and only if f(x,), a! E D converges to f(x) whenever x, a! E D converges to x in X. Every real valued continuous function on a compact space X is bounded. If A is a compact subset of X and f is a continuous function on X, then the image of A under f,i.e. f(A), is a compact subset of the real line R. Let (X, F)be a topological space and A a subset of X. Then A n .Y ' = {A nV; V E Y} is called the relative topology on A. (A, A nY) is a topological space. A is a compact subset of X if and only if (A, A n Y) is a compact topological space. Let (X, Y) be a topological space. A subset A of X is said to be dense-in-itself if there are no isolated points in A. A subset A of X is said to be perfect if it is closed and there are no isolated points in A. X is said to be scattered if no non-empty closed subset of X is perfect, i.e. every non-empty closed subset A of X contains an isolated point of A. Let X be any set. A pseudo-metric on X is a map p from the Cartesian product space X x X to [0, co) satisfying the following. (i). p ( x , x) = 0 for every x in X. (ii). p ( x , y ) = p ( y , x ) for every x, y in X. (iii). p ( x , z ) i p(x, y ) + p ( y , z ) for all x, y , z in X. A pseudo-metric p on X is said to be a metric on X if x = y whenever p ( x , y ) = 0. A pseudo-metric space (X, p ) is said to be complete if every Cauchy sequence in X is convergent, i.e.

napr

n,,,,

1. PRELIMINARIES

17

whenever x,, n 2 1 is a sequence in X and limm.n+osp(xm, x,) = 0, there x ) = 0. If (X,p) is a pseudo-metric exists x in X such that limn+osp(xn, space, there exists a complete pseudo-metric space (X, p") with the following properties. (i). x c k . (ii). ~ ( xy, ) =p(x, y ) for all x, y in X. (iii). x is a dense subset of 2, i.e. for every x' in k,there exists a sequence x,, n 2 1 in X converging to x, i.e. limn-+os b(x,, 2) = 0. (2,p") is called a completion of the pseudo-metric space (X, p ) . Every pseudo-metric space (X, p ) induces a natural topology S on X. S is the smallest topology on X containing 8 = (B(x, r ) ; x E X, r > 0}, where B(x, r ) = { y E X; p ( x , y ) < r}. Let (X, S )be a topological space. A subset A of X is said to be nowhere dense if (A)" = 0. A subset B of X is said to be of first category if B is a countable union of nowhere dense subsets of X. Baire Category Theorem : If (X, p ) is a complete metric space, then X is not of first category. A subset A of X is said to have the property of Baire if there exists an open set V suyh that AAV is of first category. The collection of all subsets of X each of which has the property of Baire is a a-field on X containing all open subsets of X. The product space C = (0, l}Ho = {(XI, x2, . . .); x i = 0 or 1 for every i 2 1) is called Cantor Set. There is a natural metric p on C defined by p ( ( x 1 , x2, . . J, ( Y l , Y 2 , *

*

.I) =

c

1

F I X "

-Ynl

n2l

for ( x I , x ~ , .. .) and ( y l , y 2 , . . .) in C. (C,p) is a compact Hausdorff totally disconnected perfect metric space. Every clopen subset of C is a finite union of sets of the form {xl} X (x2} x . x (x,} x (0,1} x ( 0 , l ) x * *, for xl, x2,. . . ,x, in (0, 1) and n 2 1. Let (X, T)be a compact Hausdorff space. The Baire a-field 90on X is the smallest a-field on X with respect to which every real valued continuous function on X is measurable. The Borel a-fieEd 93 on X is the smallest cr-field on X containing all open subsets of X. Obviously, Boc B. We now show that 3 0 is the smallest a-field on X containing all compact Gs subsets of X. Let B o o be the smallest a-field on X containing all compact Gs subsets of X. Let A be a compact Gs subset of X. By Urysohn's lemma, there exists a real valued continuous function f on X such that A = f-'({O}). Therefore, A E 90. Consequently, B o o c Wo. Iff is a real valued continuous function on X, then f-'{[k,oo)} is a compact Gs subset of X and so f-'([k, a)} E Woo. Therefore, f is measurable with respect to Boo. Hence Boc Boo. Thus we have shown that Bo= ao0. Let (X, F) be a compact Hausdorff totally disconnected space, % the field of all clopen subsets of X and Bothe Baire a-field on X. We show that the smallest a-field 9;on X containing % is Bo.Since every C in % is a compact Gs subset of X, it follows that $236 cBo. We now show that

-

18

THEORY OF CHARGES

every real valued continuous function f on X is measurable with respect to 936.For n 2 1 and x in X, let U, = {y E X; I f ( x ) -f(y)I < l/n}. U, contains a clopen set V, containing x. {V,; x EX} is an open cover for X. Let {V,,, V,,, . . . , VXk}be a sub-cover of X. Let D I = V,,, DZ= V,, -V,,, D3 = V,, - (Vxlu V,,), . . . ,Dk = V,, - (V,, U V,, U * * * U VXk-,). D1, Dz, . . . , Dk are pairwise disjoint clopen subsets of X whose union is X. Choose and fix y i in Di for each i = 1 , 2 , . . . ,k. Let k

ffl= i c f(Yi)lD*. =l Then I f n ( x ) - f ( x ) I 5 l / n for everyx in X. Consequently, limfl+mf,,(x)= f ( x ) for every x in X. Each f,,is measurable with respect to 3;.Therefore, f is Hence 9 3 6 =ao. measurable with respect to 96.

1.4 BOOLEAN ALGEBRAS The aim of this section is to present some basic ideas on Boolean algebras and prove Stone Representation Theorem for Boolean algebras. 1.4.1 Definition. A Boolean algebra is a non-empty set 5 in which two binary operations v, A (join and meet) and one unary operation " (complementation) are defined satisfying the following identities. (i). a v b = b v a , a A b = b A U for all a, b in 5. (ii). a v ( b v c ) = ( a v b ) vc, a A (b A C ) = ( a A b ) A C for all a, 6, c in 5. (iii). (a A 6 ) v b = b, ( a v b ) A b = b for all a, b in 5. (iv). a A ( b v c ) = (a A b ) v ( a AC), a v (b A C ) = (a v 6 ) A ( a v c ) for all a, 6 , c in 5. (v). ( a A a") v b = 6, ( a v a") A b = b for all a, b in B. One can show that a A a' does not depend on a in 5 and b v 6' does not depend on b in 5. Denote a A a" by 0 and a v a" by 1. If 9 is a field of subsets of a set R, then 9 is a Boolean algebra in the above sense if we identify the operation of join by union of sets, meet by intersection of sets and complementation by complementation of sets with respect to R. 0 identifies with the empty set 0 and 1 identifies with the whole space R. We introduce a partial order 5 on any given Boolean algebra 5 as follows. For a, b in B, say a 5 b if a A b = a, or equivalently, a v b = 6. The relation 5 is a partial order on B, i.e. it is reflexive (a 5 a for every a in B), antisymmetric (if a 5 b and b Ia, then a = b ) , and transitive (if a 5 b and b SC, then a IC). With respect to this partial order, a v b is the smallest

1. PRELIMINARIES

19

element in B r a and 6, a A b is the largest element in B
20

THEORY OF CHARGES

If I is an ideal in a Boolean algebra B, then J = {b E B; b ' E I} is a filter in B. If I is a maximal ideal in B, then the J defined above is a maximal filter in B. Using Zorn's lemma, one can show that there exists a maximal ideal in B containing any given ideal in B and a maximal filter in B containing ai # 0 for any any given filter in B. If J1 is a subset of B satisfying finite number a l , a 2 , .. . ,a, of elements in J1, then there exists a filter in B containing J1. If It is a subset of B satisfying V ~ =bjI f 1 for any finite number b l , bz, . . . , 6, of elements in 11, then there exists an ideal in B containing I1. As in Section 1.1, one can show that an ideal I in B is a maximal ideal in B if and only if either a or a' E I for every a in B. Similarly, a filter J in 5 is a maximal filter in B if and only if either b or bCEJ for every b in 5. Now, we describe quotient Boolean algebras. Let I be an ideal in a on B as follows. Boolean algebra B. Introduce an equivalence relation For a, b in 8, say a -b if aAb = ( a A b")v ( a "b~) E I . Let B/I denote the collection of all equivalence classes in B. For a in B, let [ a ] denote the equivalence class in B containing a, i.e. [ a ]= {b E 8 ; b a } . Note that [O] = 1. B/I can be made into a Boolean algebra. The operations v , A and ' on B/I are introduced as follows. For a, b in B,

-

-

[a1v [ b l = [ a v bl, [ a l ~ [ b l = [~a b l , [a]'= [a']. One can check that with these operations, B/I becomes a Boolean algebra. B/I is called the quotient Boolean algebra with respect to the ideal I. There is a natural map h from B to B/I defined by, for a in B, h ( a )= [ a ] .This map is a homomorphism from the Boolean algebra B onto the Boolean algebra B/I. Now, we prove Stone Representation Theorem for Boolean algebras.

1.4.6 Stone Representation Theorem. Let 5 be a Boolean algebra. Then there exists a compact Hausdorff totally disconnected space X such that 5 and the field 9of all clopen subsets of X are isomorphic. Proof. Let X be the collection of all maximal filters in B. For each a in B, let h ( a ) be the collection of all maximal filters in B each of which contains a. h has the following properties. (i). h ( 0 )= 0. (ii). h(a1 v az) = h ( a 1 ) uh(az),u l , U Z E B. (iii). h ( a l ~ u ~ ) = h ( u ~ ) n hal, ( ua~z )€ ,B . (iv). h(aF)= (h(al))",al E B. (v). h ( a l )f h(az),if at f U Z .

1.

PRELIMINARIES

21

Look at the collection 9 = {h( a ) ;a E B}. By (iii), 9is closed under finite intersections. Consequently, there exists a smallest topology S on X for We claim that which 9 is a base. .T is precisely unions of sets from 9. (X, .T)is a compact Hausdorff totally disconnected space and $is precisely the collection of all clopen subsets of X. We first show that (X, T)is a Hausdorff space. Let J1 and J2 be two distinct maximal filters in X. Then there exists a in B such that a E J1 and U'EJZ. J1ch ( a ) and J 2 € h(a'). Further, h ( a ) nh(a')= 0 . h ( a ) and h(a') are obviously open sets. Next, we show that X is compact. Since every closed set in X is an intersection of sets of the type h ( a ) , a E B, it suffices to show that for any family {h(a,); cu E r}with finite intersection property, i.e. h(a,) # 0 for any finite subset rl of r, f L G r h ( a , ) # O . For any such family {h(a,); cu E r},it follows that A a e r l a, # 0 for any finite subset rl of r. Consequently, there exists a maximal filter J 3 {a, ;(Y E I?}. Obviously, J E n E rh (a,). Hence X is compact. Since 9is closed under complementation, every set in 9is clopen. O n the other hand, let V be. a clopen subset of X. Since V is open, it is a union of sets from 9. Since V is closed (hence compact), this union admits a finite subcover for V. Since 9is closed under This shows that 9 is precisely the collection of all finite unions, V E 9. clopen subsets of X. It is obvious that (X, S)is totally disconnected because 9is a base for S. The map h defined from B to 9is an isomorphism. Hence B and 9are isomorphic. This completes the proof. 0

We call X given above the Stone space of 9. Let B be a Boolean algebra. a and b in B are said to be disjoint if a A b = 0. A subset {a, ;cu E r}of B is said to be pairwise disjoint if a, A a. = 0 for every (Y # p in r. We give a sufficient condition for a Boolean u-algebra to be complete. First, we need a definition.

1.4.7 Definition. A Boolean algebra B is said to satisfy the countable chain condition if every collection {a,; cu E r}of pairwise disjoint elements in B is at most countable. 1.4.8 Theorem. Let B be a Boolean u-algebra satisfying the countable chain condition. Then B is a complete Boolean algebra. Proof. Let {b, ;cu E r}c 5. We use Zorn's lemma to show that V,€r 6, exists in B. Let V = {C c B; the elements of C are pairwise disjoint, each element of C is non-zero and s b , for some cu in r}.Clearly, V is non-empty. On V,we introduce a partial order as follows. For C1, C2 in V,say C I S CZif C, E V and is an upper C1 c C2. Let {C, ; S E T} be a chain in V.Then USET bound of the chain {C, ; 6 E T}. Let Co be a maximal element in V. Since

22

THEORY OF CHARGES

B satisfies the countable chain condition, CO is countable. Let CO= {cl, cz, . . .}. Since 5 is a Boolean a-algebra, z = VnZlc, exists in B. We

show that z is indeed the supremum of all b,, a E r. For this, we first show that z z b, for every a in r. Suppose this is not true. Then there exists a0 in r such that d = b,, - z = b,, - VnZlc, # 0. This implies that d A c, = 0 for every n z 1. So, Cou { d } E %' contradicting the maximality of CO.Thus z is an upper bound of all b,, a E r. Let z ' z b, for every a in r for some z' in B. We show that Z ' Z Z . Since C0€%', for every n 2 1, there exists a , in r such that c, 5 ban for every n P 1.So, z=

v

nrl

Hence z

=Veerb,.

c,s

v

b,,,

SZ'.

nzl

0

1.4.9 Definitions. Let B be a Boolean algebra. (1). An element a in B is said to be an atom of B if the following conditions are satisfied. (i). a # 0. (ii). b € 5 ,b S a J b = 0 or b = a . (2). B is said to be atomic if for every non-zero element b in B, there exists an atom a of B such that a 5 b. (3). B is said to be nonatomic if there are no atoms in B. 1.4.10 Theorem. Let B be a Boolean algebra. Then B is nonatomic if and only if its Stone space X is perfect. Proof. Let 9be the field of all clopen subsets of X and h the isomorphism from B to $. Note that a E B is an atom of B if and only if the clopen set h ( a ) does not contain properly any non-empty clopen subset of X. h ( a ) has such a property if and only if h ( a ) is a singleton set, i.e. h ( a ) is an isolated point of X. If x in X is an isolated point of X, then { x } is a clopen subset of X and hence there exists a in B such that h ( a )= { x } . Since x is isolated, a is an atom of B. Hence B is nonatomic if and only if X is a perfect set. 0 We end this section with some observations on homomorphisms between Boolean algebras and induced maps on their Stone spaces. Let A and 5 be two Boolean algebras and h a homomorphism from A to B. Let X and Y be the Stone spaces of A and B respectively. We define a map T from Y to X as follows. Let J E Y. J is a maximal filter in B. Let T(J) = {d E A; h ( d )E J} = h-'(J). It can be checked quite easily that T(J) is a maximal filter in A. (See Remark 1.1.23 (8).) Thus T(J) E X. Thus we have defined a map from Y to X. We now show that T is a continuous map from Y to X. Let C be any clopen subset of X. Then there exists a in A such that C = {I E X; a E I}.See Theorem 1.4.6. Then

1.

PRELIMINARIES

23

T-'(C)={JEY; T(J)EC}={JEY;h-'(J)EC} = {J E Y; a E h-'(J)} = {JEY; h ( a ) E J}.

From the description of the clopen subsets of Y, it follows that T-'(C) is a clopen subset of Y. Hence T is continuous. The following theorem describes the duality between h and T.

1.4.11 Theorem. The following statements are true. (1). h is onto if and only if T is a one-to-one map. (2). h is one-to-one if and only if T is an onto map. Proof. (1).Let J1 and J2 be two distinct elements in Y. We show that T(J1) and T(J2) are distinct. By Remark 1.1.23(9), there exists b in B such that b E J1 and b ' E J2. Since h is onto, there exist al, a2 in A such that h(al) = b h(a2)= 6'. Therefore, al E T(J1) and u2E T(J2). If T(J1) = T(J2), then al, a z ~ T ( J 1 ) and so, a1A U ~ E T ( J ~This ). means that h(a1 A U Z ) = h (al)A h ( a 2 )= b A 6' = 0 E J1. Then J1 cannot be a maximal filter in 5. This contradiction shows that T(J1)and T(J2)are distinct. The converse can be proved analogously. (2). Suppose h is one-to-one. Let I E X. We will exhibit J in Y such that I = T(J).Let J1 = {h (a);a E I}. J1 has the following property. h (al)A h (a2)A - A h(a,)#O for any finite set {al, U Z , . . . , a,}cI. For, AY=1h ( a i ) = h(AY=l a<)# 0 ash is one-to-one and ai # 0. By Remark 1.1.2314) and Zorn's lemma, there exists a maximal filter J in B containing J1. It is now obvious that T(J)=I. Hence T is onto. The converse can be proved analogously. 0 This completes the proof.

1.5 FUNCTIONAL ANALYTIC CONCEPTS In this section, our main goal is to present some ideas on vector lattices and prove Riesz Decomposition Theorem. Riesz Decomposition Theorem is one of the main tools we use in the study of finitely additive measures. The other relevant functional analytic concepts used in this book are also compiled in this section mostly without proofs. We begin with vector lattices.

1.5.1 Definition. Let L be a vector space over the real line R which is endowed with an order structure defined by a reflexive, transitive and anti-symmetric binary relation denoted by 5.(L, s)is called an ordered vector space if the following hold. (i). x, y E L , x s y + x + z s y + z for all z in L. (ii). x, y E L, x 5 y +cx s cy for every c in [O,OO).

24

THEORY OF CHARGES

Let (L, I) be an ordered vector space. For x, y in L, an element z in L with the properties (i) x I2, (ii) y Iz , and (iii) z 5 z f whenever z f E L, x 5 z ’ and y 5 2 ’ (i.e. z is the least element in L dominating both x and y ) is called the supremum of x and y and is denoted by Sup {x, y} or by x v y. Clearly, Sup {x, y}, when it exists, is well defined. For any subset {xu; a E r} of L, supremum of {x, ; a E r} is defined analogously and is denoted by Vasrx, if the supremum exists. Similarly, for x, y in L, an element u in L with the properties (i) u Ix, (ii) u 5 y and (iii) u f 5 u whenever u’ E L, u ’ s x and U’I y, is called the infimum of x and y. It is denoted by Inf {x, y} or by x A y. Clearly, Inf {x, y} is well defined when it exists. For any subset {x, ; a E r} of L, infimum of {xu;(Y E I?} is analogously defined and if the infimum exists, it is denoted by A,.r x,.

1.5.2 Definition. An ordered vector space (L, I) is said to be a vector lattice if Sup {x, y} and Inf {x, y} exist for all x and y in L.

1.5.3 Definition. Let (L, 5)be a vector lattice. For x in L, define x+ = x v O , x - = ( - x ) v O a n d ~ x ~ = x + + x x - . x + , x - a n d ~arecalledthepositive x~ part, negative part and the modulus of x respectively. For x , y in L, x and y are said to be orthogonal if Ix I A Iy I = 0. In such a case, we use the notation x I y.

The following theorem gives some elementary identities that hold in any vector lattice.

1.5.4 Theorem. Let (L, I) be a vector lattice and {xa ;a E r}a non-empty subset of L. Then the following are true. (1). If, for x in L, one of V a a r X , and VmEr(x +x,) exists, then the other exists and x+ x, = (x +xu).

v

v

,er

(2). If, for x in L, one of A m c rx, and A u e r (x +x,) exists, then the other exists and x + A x, = A (x +xu). ,Er

(3). If one of Veerx, and A,.r

V

,cr

(-xa) exists, then the other exists and

X, = -

A

,.r

(-x,).

x, and Va.r Px, exists, then the other exists

(4). For-@> 0, if one of and

,Cr

P(

v x,) = ,erv Px,.

,Gr

( 5 ) . For P >O, if one of AUErxOI and A,.r Px, exists, then the other exists and P( A x,) = A Px,. ,or

,Er

1.

25

PRELIMINARIES

(6). (x v y ) + (x A y ) = x + y for every x, y in L. (7). x = x + - x - f o r e v e r y x i n L. (8). x + A X - = 0 for every x in L. (9). 1x1 = x + v x - = x v (-x) = x + + x - for every x in L. (10). Forx, y , z in L, if x = y -2, y 2 0 , z 2 0 , then y ? x + a n d z Z x - . (11).Forx, y , z in L , i f x = y - z and y A Z = 0 , then y = x + and z =x-. (12). For x in L, 1x1 = 0 if and only if x = 0. ForAin R a n d x i n L,IAnI=lAlIxl. F o r x , y i n L,Ix+ylrlxl+lyl. (13). Forx in L , x + = $ ( l x l + x ) andx-=$(lxI-x). (14). Forx, y in L , - I x l - l y l r x A Y IX v y IIxI+lyl. (15). F o r x , y i n L , ( x - Y ~ = ( x v Y ) - ( x A Y ) . (16). For x, y in L, x v y = $(x + y + Ix -yl). (17). Forx, y i n L , x ~ y = 1~ ( x + y - I x - y ( ) . (18). F o r x , y i n L , IxIvIyI=3(1x+yl+Ix-yI). (19). Forx, y i n L, ( x I ~ ( y I = 3 ( 1 1 x + y I - I x - y I I ) . (20). Forx, y in L, x s y if and only if x c s y c and y - l x - . (21). Forx, y i n L , x I y i f a n d o n l y i f (x+yl=Ix-yl. (22). Forx, y i n L,xIyifandonfyifIxIvlyI=IxI+I~I. (23). For x , y in L, if x Iy , then (x + y)' = x++y+ and (x + yl = /xl+\y\. (24). Distributive laws hold. If V,.rX, exists, then for any x in L, V a c r(x A x,) exists and x A (

v

.a)=

asi-

v

(XAX,).

,€I-

If A a E rx, exists, then for any x in L , A U E(x r v x,) exists and

(25). F o r x , y i n L,Ix+yIs21xIv21yl. (26). For x, y in L, if x Iy and A E R, then Ax Iy. (27). F o r x , y , z i n L , ~ ( x v z ) - ( y v z ) ~ + ~ ( x A z > - ( y A z ) ~ = ~ x - y ~ . (28). F o r x y , x l , y 1 in L , I(x v y ) - ( x l v y l ) l ~ ~ x - x l ) + l y - y ~ l . (29). F o r x , y , x l , y l in L, I ( x ~ y ) - ( x l A y l ) l s I x - x l l + l y - Y 1 I . Proof. (l),(2),(3), (4)and ( 5 ) follow directly from the definitions involved. (by (3)) (6). x + y -(x A y ) = x + y +[(-x) v ( - y ) ] = [(x

+ Y ) -x 1 v "x + Y 1- Y 1

=yvx=xvy. (7). x + - x - = ( x v 0 ) - " ( - x ) v 0 ]

(by (1))

26

THEORY OF CHARGES

(8). (x+ v X- ) + (x+ A X- ) = X + + XIt suffices to show that x + v x - = x + + x - . Observe that x++x- = x +x- +x-

+ 2[(-x) v 01 = x + [(-2x) v 01 =x

= (x -2x)

vx

= x v (-x)

= x v (-x) v o = (x v 0) v [(-x) v 01 + =x v x .

(Note that x v (-x)zO. For, x s x v (-x) and -x

XI

v (-x),

and so 0 4

2[x v (-x>l.)

(9). The proof of this is included in the proof of (8). (10). x = y - z implies that y -x = z 2 0 . So, y r x . Since y 2 0 , y z-x v O = x + . Similarly, one can show that z r x - . (11). Y A Z = O implies that y r O and 2 2 0 . By (lo), O ~ y - x + s y and OZSZ-X-CZ. Since y ~ z = O , ( Y - x + ) A ( z - x - ) = O . Since x = y - z = x + - x - , y -x+= z -x-. Hence y - x + = 0 = z -x-. (12). This follows from what we have proved above. (13). This follows from (7) and the definition of 1x1. (14). It is enough to observe that x v y I Ix I + Iy 1 which is obvious. (15). BY (I), (2) and (31, x +(y - x ) + = x +[(y - x ) v O ] = [x

+ (y -x)]

v (x

+ 0)

=xvy. X

- (X - )J)'=X

- [(X - y) V 01 = X

[(y -X)

=[X +(y -X)]A (X+o)

= X AY.

Consequently, (X V y ) - (X

A

y ) = (y -X)'+

(X

- y )'

=(x-y)++(x-y)= Ix -yI.

(16). This is a consequence of (6) and (15). (17). This is a consequence of (6) and (15).

A

01

(20). x 5 y implies that (x v 0) 5 (y v 0). This means that x + Iy+. Similarly, one can show that y - s x - . The converse is trivial. (21). This follows from (19). by (61 122). (1x1 v lY I>+(lxl A IY I ) = I X l + l Y I, From this identity, (22) follows obviously. (23). If x I y , then (by (6)) 0 = 1x1A IY I = 1x1+ lY I - (1x1 v lY I)

I + IY I -%lx + Y I + Ix - Y I) = 1x1+ IY I - Ix + Y I Hence, we have the equality Ix I + Iy 1 = lx + y I. Further, (x + y)' = (x + y) v 0 = $(x + y + Ix + y I) = Ix

=ax +Y

(by (18)) (by (21))

(by 16))

+IXI+lYl)

(by what we have proved above) =x++y+. (24). Let y =.VaErx,. Then x A X , 5 x A y for every a in r. We show that Let w E L and x AX, 5 w for every a in r. By (6), x + x , - ( x v x , ) ~ w for every a in r. By (l), w + ( x v y ) r x + y . So,

VaEr(x AX,)= x A y.

28

THEORY OF CHARGES

w z x + y - ( x vy)=x AY. Hence V a , r ( X AX,)=X A Y = X ~ ( V ~ ~ r x ~ ) indeed. The other law can be established analogously. (25). This follows from (18). . z r O and z s (26). Case ( i ) . I A l r l . Let z = I A x l ~ l y l = l A l I x I ~ l y JThen IAllx] and s l y l . From this, it follows that (l/lAI)z 11x1 and (l/IA])z s l y ] . Since 1x1A IyI = 0, z I0. Hence z = 0. Case (ii). l A l < 1. If A = 0, there is nothing to prove. Let \A 1 > 0. Find c > 1 such that c IA I = 1. Then x I c y , by case (i). This means that Ix 1 A c Jy1 = 0 = c JA 11x1A cly I = c (Ih1 Ix 1 A ly 1) which implies that [A 1 (xI A ly I = 0. (27). Using (15) and the distributive laws, we obtain I(x VZ)--(Y v z ) l + l ( x Az)-(Y A Z ) I

=(x v z ) v ( y V Z ) - ( X V Z ) A ( Yv z ) + ( x A Z ) V ( YA Z ) - ( X A Z ) A ( Y A Z ) = (X v y v 2)-(X

A

y ) v z +(x v y ) A z -(x

=[(X Vy)VZ+(X VY)AZ]-[(X

"(x

vy>+zI-[(x

=(X Vy)-(X

A

y

A2)

AY)VZ+(X A y ) A Z ]

AY)+ZI

AY)=IX-Y(

(28). I(x v y ) - ( x i v y i ) I = I ( x

(by (15 ) ) .

vy)-(xivy)+(xivy)-(xivyi)I

s I ( x VY)-(X1 VY)l+l(Xl VY)-(X1 V Y d l SIX

(by (6))

-x1l+Iy -Y1l

(29). This is similar to the above. This completes the proof of all the identities.

(by 12)) (by (27)).

E l

An important example of a vector lattice is the space of all bounded finitely additive measures to be presented in the next chapter. The above theorem brings into focus many facets of the main object of study in this book. Now, we introduce some important concepts such as normal sublattices and boundedly complete lattices.

1.5.5 Definition. Let (L, 5)be a vector lattice and W c L. W is called a sublattice of L if W is a vector subspace of L and x v y E W, x A y E W for every x, y in W. 1.5.6 Definition. A vector sublattice W of a vector lattice (L, 5)is said to be normal if the following conditions are satisfied. (i). x EW, O s l y ) ~ I x I + yEW. (ii). If V a E r x , exists for a given non-empty (xp; (Y E r}cW, then Vaar xa EW.

1.

29

PRELIMINARIES

1.5.7 Definition. Let (L, I) be a vector lattice and S c L. The orthogonal complement of S is denoted by S’ and is defined by

sL= { y EL; y IX

for every x in s}.

It is easy to check that for any S c L, S nSL= 0 or = (0).If SI c SZ c L, then S: c S:. The following theorem shows that normal sublattices arise in a natural way. 1.5.8 Theorem. Let (L, 5) be a vector lattice and S c L. Then SL is a normal sublattice of L.

Proof. First, we show that S’ is a vector subspace of L. Let y , z c, d real numbers. Then for any x in S,

E S’

and

0 s KCY +dz)l A 1x15 (2lCllY I v 2ldl lzl) A 1x1

I I A Ix I) v (14Jz I A Ix 111.

= 2HlC IY

The second inequality above follows from Theorem 1.5.4(25) and the equality from Theorem 1.5.4(24). Since y I x and z Ix,cy Ix and d z Ix. See Theorem 1.5.4(26). Hence (cy + d z ) I x . So, c y + d z ES’. Next, we show that for y , z ES’, y v z ES’ and y A Z ESI. But these follow from Distributive laws. Thus we have proved that S’ is a vector sublattice of L. The normality of S’ again follows from distributive laws.

1.5.9 Definition. A vector lattice (L, 5)is said to be boundedly complete if for every non-empty subset {xa ;a E r}of L bounded above, i.e. there is an element x in L such that x, IX for every a in r, Vol.rX, exists. If (L, 5)is a boundedly complete vector lattice and if {x, ; a E r} is a non-empty subset of L bounded below, then A a E r x aexists. This follows from Theorem 1.5.4(3). The following is the main theorem of this section.

1.5.10 Riesz Decomposition Theorem. If S is a normal vector sublatfice of a boundedly complete vector lattice (L, a),then any element x in L can be written as a sum x f + x ” for some X I in S and XI’ in S’, and this decomposition is unique. Further, if x 2 0 , then x f = VYEs(x A Iyl). For x in L, in general, x’= (x+)’- (x-)’. Proof. First, assume that x 2 0. Then the set {x A J y1; y E S} is bounded (x A ly 1) exists. Define x f = above, and as L is boundedly complete, VYEs V,,S (x A Iyl). As S is normal, x A I y l S~ for every y in S and consequently, x f E S. Now, we show that x - X ’ E S’. Let y E S and u = (X - x f ) A Iy(. The problem reduces to showing that u = 0. Since 0 5 u 5 Iy 1 and y E S, u E S. Since S is a vector space, u + x ’ E S . Note that u + x l ~ ( x - x f ) + x l = x .

30

THEORY OF CHARGES

Consequently, u + x ~ = ( u + x ' ) A = x I U + X ' ~ A= X x A I u + x ' I ~ x 'from the definition of x'. This implies that u 5 0 . Hence u = 0. Thus x - X ' E S'. Denote x - x r by xN. Thus, we have achieved in writing x =xr+xr' with X ' ES and xrrE S'. Now, we obtain a decomposition for any x in L. Write

x = x + -x

-=

(X+)'+ (X+)r'- ( f ) ' - (x-)"

= [(x +)' - (x-)'I

+ [(x

+)'r

- (x-)"] = x r + X I ' ,

say.

It is obvious that X ' E S and X " E SI. Thus x = x ' + x B is a decomposition of x with the desired properties. To prove uniqueness, let x = X I + x2 = y1+ y 2 with x l , y l in S and x2, y 2 in SL.Then x l - y l € S and x 2 - y 2 ~ S ' . Since xl-yl=-(x2-y2), (x1-yl)ES' as well. This implies that Ixl-yll=O or x l = y l . See Theorem 1.5.4(12). We also obtain x 2 = y 2 . Hence the decomposition obtained above is unique with the stated properties. 0

1.5.11 Corollary. If S is a normal vector sublattice of a boundedly complete vector lattice (L, s),then (S')' = S . Proof. The result follows from the following relations. (i). L= SOS'. (ii). L = s'o(s')'. (iii). s c (S')'. (Here, 0 denotes the direct sum of the sets involved.)

0

Now, let y E L be fixed. We characterize the smallest normal vector sublattice of (L, 5)containing y .

1.5.12 Theorem. Let (L, 5)be a boundedly complete vector lattice and y E L . Then the smallest normal vector sublattice of L containing y is (S')', where S = { y } . Further, x E (S')' if and only if x=

V

n>l

(x+AnlyI)-

V (x-Anlyl). fl2l

Proof. Since S c (S')', (S')' is a normal vector sublattice of L containing y . If S1 is a normal vector sublattice of L containing y , then S c S 1 . This implies that S: c S'. From this, it follows that (S')' c (S:)'= S1. Hence (S')' is the smallest normal vector sublattice of L containing y . Thus the first part of the theorem is proved. Since (S')' is a normal vector sublattice of L, it follows that x=

V fl2l

(x+AnlyI)-

V

(x-Anlyl)E(S')'.

flZl

Conversely, let x E (S')' and assume that x 2 0 . Let u = Vfl21(x A nlyl). We show that u = x. If we show that ( x - u ) A Iy I = 0 , it would then follow that x --u E S' from the definition of S'. Since (S')' is normal, u E (S')'.

1. PRELIMINARIES

31

Since x E (S')I, x - u E (S')'. Thus we find that x - u is available in both S' and (S')I. This implies that x - u = 0 or x = u. In view of this argument, let us show that (x - u ) A 1y(= 0. To this end, we note (X - U ) A

IY 15((X

- U ) Ax) A

IY I = (X - U )

A (X A

IY 1)

5 (X - U ) A U.

By Theorem 1.5.4(2), we also note that [(x - u ) A u ] + u = x (X - U ) A U = -24 +(X A

A

2u. So,

2U) by Theorem 1.5.4(4)

=-U+(

v (XA2XnIyl))

nz1

=-u+u=o.

Hence 0 5 (x - u ) A IyI 5 (x - u ) A u = 0. Thus (x - u ) A IyI = 0. So, if x E (S')I and x 2 0 , the above representation is valid. If x E (S')' is any general element, write x = x + - x - . Note that x+, X - E (S')I. By what wehaveprovedabove,x+=V,,I ( x + ~ n l y l ) a n d x - = V , , ~( x - ~ n ( y l ) . T h i s 0 completes the proof of the theorem. Now, we provide a brief review of other relevant functional analytic concepts used in the book. First, we introduce vector spaces over the field of rational numbers which is specially required in Chapter 3.

1.5.13 Definition. Let Q be the field of all rational numbers. A vector space or a linear space over Q is an additive group L (with the additive operation denoted by +) together with a map m from the product space Q x L into L written as rn (r, x) = rx for r in Q and x in L, which satisfies the following four conditions. (i). r ( x + y ) = rx + r y , r E Q , x, y EL. (ii). (r +s)x = rx +sx, r, s E Q and x E L. (iii). r ( s x )= (rs)x, r, s E Q and x EL. (iv). l ( x) = x, x E L. The usual concept of a vector space over the real line R has the same description as the above with Q replaced by R. If L is a vector space over Q, a linear functional on L is any map T from L to R satisfying T(rx + sy) = r T ( x )+ s T ( y ) for all r, s in Q and x, y in L.

32

THEORY OF CHARGES

Let L be a vector space over Q. A susbset A of L is said to be a Hamel Basis for L if every non-zero x in L admits a unique representation x =rlxl+r2x2+* *+r,x,

for some non-zero r l , r2, . . . , r, in Q , xl, x2, . . . ,x, in L and n 5 1.A subset B of L is said to be linearly independent if rl = r2 = * * * = r, = 0 whenever rlxl+ r2x2+ * +r,x, = 0 for some rl, r2, . . . ,r, in Q, xl, x2, . . . ,x, in B and n L 1. Given any linearly independent subset B of L, one can find a maximal linearly independent set A containing B. A subset A of L is a maximal linearly independent set in L if and only if A is a Hamel Basis for L. Consequently, given any linearly independent subset B of L, one can find a Hamel Basis for L containing B.

--

The following is a version of Hahn-Banach Theorem.

1.5.14 Theorem. Let L be a vector space over Q. Let L1 be a subspace of L, i.e. rx +sy E L1 whenever x, y E L1 and r, s E Q. Let x be an element of L which is not a member of L1. Let c be any real number. Let T1be any linear functional on L1. Then there exists a linear functional T on L with the following properties. (i). T ( y )= T l ( y )for all y in L1. (ii). T ( x )= c. Proof. Let B1 be a Hamel Basis for L1 and B = B1 u {x}. Note that B is a linearly independent set. Let A be a Hamel Basis for L containing B. Define T on A as follows. T ( y )= T,(y), if y E B I , = c,

if y =x,

= 0,

otherwise.

T can be extended to L in the obvious fashion and this extension, denoted 0 again by T, is the desired linear functional. The following is generally known as Hahn-Banach Theorem.

1.5.15 Theorem. Let L be a vector space over the field of all real numbers R. L e t p be a real valued function on L satisfying p ( x + y ) l p ( x ) + p ( y )for all x , y in L and ~ ( c x=) c p ( x )for all c 2 0 and x in L. Let L1 be a subspace of L and T1a linear functional on L1 satisfying T l ( x )l p ( x ) for every x in L1. Then there exists a linear functional T o n L having the following properties. (i). T ( x )s p ( x ) for every x in L. (ii). T ( x )= T l ( x )for every x in L1.

1. PRELIMINARIES

33

Now, we introduce normed linear spaces. Let L be a vector space over R. A pseudo-norm on L is a map p from L to [O,m) with the following properties. (i). p ( x ) = 0 if x = 0. (ii). p ( c x )= I c l p ( x ) for every c in R and x in L. (iii). p ( x + y ) ~ p ( x ) + p ( yfor ) all x , y in L. A pseudo-norm p on L induces a pseudo-metric p on L as follows. For x , y in L, let p ( x , y ) = p ( x - y ) . A vector space L equipped with a pseudo-norm p is said to be complete if the pseudo-metric space (L, p ) is complete, i.e. every Cauchy sequence in L is convergent under the pseudo-metric p. In what follows, we assume that all vector spaces are over R. A pseudonorm p on a vector space L is said to be a norm if x = 0 whenever p ( x )= 0. If p is a norm on L, it is customary to denote p ( x ) by llxll for x in L. The is called a normed linear space. If L is complete under the pair (L, ~~~~~) norm 11 * 1 , then (L, 11 * 11) is called a Banach space. Let (L, 11 * 11) be a Banach space. Then the topology induced by the norm II.II on L is called strong topology on L. If x , x,, n 2 1 is a sequence in L such that x,, n z 1 converges to x in the norm II-II, i.e. lim,+m IIx, - X I ] = 0, we say that x,, n 2 1 converges to x strongly or x,, n 2 1 converges to x in L. If (L, II-II) is a Banach space, then the space of all continuous linear functionals on L is called the dual space of L and is denoted by L*. For any linear functional T on L, one defines IITII = Sup { I T ( x ) l ;x EL, IIxII I1). T E L* if and only if llTll< 00. In fact, T is continuous if and only if there exists a positive constant k such that l T ( x ) l s kllxII for all x in L. If T E L*, then IT(x)l ~IITllllxllfor all x in L. The function II.II on L* is indeed a norm on L". (We use the same symbol 11 11 for both L and L* and it should be clear from the context which norm we are dealing with.) Moreover, (L*, 11 * 11) is a Banach space. If (L, II-II) is a Banach space, the weak topohgy on L is the smallest topology on L with respect t o which every T in L* is continuous. A net x,, a E D in L is said to be weakly convergent to a x in L if T(x,) = T ( x ) for every T in L". A sequence x,, n 2 1 in L is a weak Cauchy sequence if lim,,,,m T ( x , - x m ) = 0 for every T in L*. The following is an important result which we have an occasion to use.

1.5.16 Theorem. Let (L, 11 * 11) be a Banach space. Then every weak Cauchy sequence x,, n 2 1 in L is norm bounded, i.e. Sup nzl IIx,]]< 00. Let (L, II.II) be a Banach space. A subset A of L is said to be weakly closed if A is a closed set in the weak topology on L. Equivalently, if x,, a E D is a net in A converging weakly to x in L, then x E A. In this context, we quote a result.

-

1.5.17 Theorem. Let (L,11 11) be a Banach space and LI a closed (in the strong topology on L) subspace of L. Then L1 is weakly closed.

34

THEORY OF CHARGES

A Banach space (L, II-II) is said to be weakly complete if every weak Cauchy sequence in L is weakly convergent. Finally, we close this section with Banach lattices.

1.5.18 Definitions. A vector lattice (L, 5)is said to be a normed vector lattice if there is a norm 11 )I defined on L such that IIx 11 IIIy 11 whenever x , y E L and 1x1Ily 1. A Banach lattice is a normed vector lattice (L, I) with a norm 11 * 11 such that (L, 11 11) is a Banach space.

-

-

1.5.19 Theorem. In any normed vector lattice (L, 5,(1 II), the maps (x, y ) + A y from LX L to L are uniformly continuous. Hence for any subset S of L, SL is a closed subspace of L. In particular, any normal vector sublattice of L is closed. x v y and (x, y ) + x

Proof. For any x in L, observe that IIx)]= )IIx 11). Now, the uniform continuity of the maps (x, y ) + x v y and ( x , y ) + x A y from L x L to L follows from Theorem 1.5.4 (28) and (29). The rest of the assertions also follow from the.same observations. 0

CHAPTER 2

Charges

In this chapter, we introduce the main concern of this book, namely charges. They are usually known as finitely additive measures in the literature. We chronicle most of the rudimentary facts about charges in this chapter. In Section 2.1, basic concepts about charges are presented. The space of all bounded charges on a field of sets is shown to be a boundedly complete vector lattice in Section 2.2. Sections 2.3 and 2.4 deal with measures. Jordan Decomposition theorem and Hahn Decomposition theorem for charges not necessarily bounded are covered in Sections 2.5 and 2.6, respectively.

2.1 BASIC CONCEPTS This section is mainly devoted to the study of various properties of charges.

2.1.1 Definitions. Let 9be a field of subsets of a set 0. (1). A map p : 9+[-m, m] is said to be a charge on 9 if the following conditions are satisfied. (i). p ( 0 )= 0. (ii). If A, B ~ . F a n d A n B = 0 ,t h e n p ( A u B ) = p ( A ) + p ( B ) . (2). A charge p on 9 is said to be a real charge if -m
36

THEORY OF CHARGES

additive-classes of sets or Boolean algebras. In fact, there are some situations in the subsequent chapters where we deal with charges on these general domains. If p is a charge on a field 9 of subsets of a set a,p cannot take both the values 1-00 and -00. For, if A, B in 9 are such that p (A) = 00 and p (B) = -03, then p (a) = p (A) p (A")= 00 = p (B) p (B') = -a,a contradiction. The following proposition gives some properties of charges. In this proposition, p stands for a charge on a given field 9 of subsets of a set a.

+

2.1.2 (i). then

+

Proposition If F1, FZ, . . . ,F, are any finite number of pairwise disjoint sets in F,

(ii). If E , F E E E c F and -co
P ( F o ) C~ PLFi). i=l

In particular,

(v). If F E F u n d p ( F ) < m , thenp(E) -00, then p ( E )> -a for any E in 9with E c F. (vii). If F E s u n d -00
C

?I21

p(E,)s~@).

(ix). p is modular, i.e. p (E)+ p (F)= p (E u F) + p (E nF) for any E and F in 9. then (x). If F1, Fz, . . . ,F, are any finite number of sets in 9,

2.

37

CHARGES

Proof. (i) follows by induction. (ii) and (iii) are easy to prove. n-1 (iv). Let El = FI, E2= F2 - F1, E3 = F3- (F1u F2), . . . , En = F, - (Ui=,F;). Then El, Ez, . . . ,En are pairwise disjoint, Ei c F i for every i = 1,2,. ,n and Fi = Ei. Consequently,

uysl u:='=,.

P ( F o ) ~ P ( G F ~ ) = P ( G Ei ~ = l )p(Ei) = I

C

i=l

pLFi).

(v), (vi) and (vii) are easy exercises. E i c E , and SO ELl p ( E i ) = @ ( U z E 1 i)I (viii). For every m 21, p(E). Hence Cizl p ( E i ) I p ( E ) (ix). Note that p(E)+ p (F)= [ p (E n F) + p (E-F)] + [ p ( E n F) + p (F-E)]. On the other hand, p ( E u F) + p (E n F) = p(E-F) + p (F-E) + p ( E n F) + p (E nF). Hence (ix) follows. (x). This is a generalization of (ix) and can be proved by induction. The result is true for n = 2 by (ix). Suppose the result is true for n = m. We prove the result for n = m + 1. Let F1, F2, . . . ,Fmcl be any m + 1 sets from 9. Then

uEl

m+l

2 i=l

m

p(Fi)= C p(Fi)+F(Frn+l) i=l

i<j

+p(c

~ i ) ]

+tL(Fm+1)

i<j

(by induction hypothesis)

(u:,

(by using the induction hypothesis for the sum p n = 2). Continuing this way, we get the desired equality.

Fi)+ p (F,+I) with

W e give some examples of charges.

2.1.3 Examples. (1). Let R be the set of all rational numbers in [0, 1) and 9= {Uy=,[ai,bi) n a;[ai, bi)n [ a , b j )= 0 for i # j , 0 I ai I bi I 1 for every i,

38

THEORY OF CHARGES

ai, bi rational for every i and n L 1). 9 is a field on R. For any set described above. let

Then p is a positive bounded charge on 9.

.

(2). Let 0 = {1,2,3, , .), 9 ={A c R; A or A" is finite}, and p on 9 be defined by if A is finite and has n elements, p(A) = n, = -p (A'), if A" is finite.

Then p is a real charge on 9 but not bounded. (3). Let 9 be a field of subsets of a set R and 4 a maximal ideal in 9. Define p on 9by p(F)=O, ifFE.9, = 1, if Fa$, F E ~ . Then p is a charge on 9. Conversely, if p is a 0-1 valued charge on 9,then 4= {F E 9; p (F)= 0) is a maximal ideal in 9and 8; = {EE 9; p (E) = 1) is a maximal filter in 9. Consequently, the Stone space of 9 can be identified as the collection of all 0-1 valued charges on 9.See Theorem 1.4.6.

(4). Let SZ={l, 2 , 3 , . . .}. There is a 0-1 valued charge p on P(R) such that p (A) = 0 if A is a finite subset of SZ. This can be shown as follows. Let = {A c SZ; A is finite}. 4l is an ideal in 9(R). There is a maximal ideal 4 in P(R) containing 4 1 . (See Section 1.2.) Define p on P(SZ)by p(A)=O, if A E ~ ,

=1, ifAa4. p

is the desired 0-1 valued charge on P(SZ).

(5). Let R = [0,1) and 9 the collection of all sets each of which is a finite disjoint union of intervals of the type [a, 6) with O s a 5 b 5 1. Let cp be any real valued function defined on [0,1]. Define pQ on 9 as follows. For O s a 5 6 ~ 1 pQ([a,b))=cp(b)-cp(a). , For any F in 9, pQ(F)is defined additively. Then pQ is a real charge on 9.

(6). A special case of the above is given by the function cp defined as follows. cp (x) = 0,

= n,

if x is irrational, x E [0, 11,

if x is rational, x = m/n, m and n are mutually prime integers, x

=0, ifx =O.

E (0,1],

2.

39

CHARGES

In this example, p+, is unbounded on every non-empty set in 9, i.e. Sup {lp (E)I; E c F, E E f l =a3 for every non-empty set F in 9?

(7). Another special case of ( 5 ) is the following. Cp(O)=O and ~ p ( x ) = l/x,

if O < x

I1.

In this case, prpis unbounded on every set in 9containing 0.

(8). B a n a c h Limits a n d Shift-inuariant Charges. Let a={1,2,3, . . ,}, 8 = the shift transformation from R to R defined by S ( n ) = n + 1 for n E a.We show that there exists an S-invariant probability charge p on 9,i.e. p is a probability charge on 9 and p (A) = p (S-'(A)) for every A c R. We use Banach Limits, which we shall now describe, to show the existence of charges of the type described above. Let embe the space of all bounded sequences of real numbers. For x = (xl,x 2 , . . .) E em,let llxllm = Sup,,, IX,,~. (em, 11 * Ilm) is a Banach space. Let

S(a)and S

L={Y

woo}.

= ( Y 1 , y 2 , . . . ) ; ( Y ~ , Y ~ + Y ~ , Y ~ + .Y. ~ + ~ ~ ,

It is clear that if y = ( y l , y 2 , . . .) E L, then y,, n 2 1 is a bounded sequence of real numbers and that L is a subspace of Em. For x E em,let p ( x ) = Sup,,,l x,,. We show that p ( .) has the following properties. (i). p ( c x ) = c p ( x ) for x and c 2 0 . (ii). p ( x + y ) s p ( x ) + p ( y ) for all x, y €ern. (iii). p ( y ) 2 0 for y E L. (i) and (ii) are obvious. We prove (iii). Suppose p ( y ) = Supnzl y n = k < O for some y = ( y l , y 2 , ...) EL. Then y l + y 2 + . . . + y n s n k for every n z l . So, y + y2 + * * + y,,, n 2 1cannot be a bounded sequence of real numbers. This contradiction shows that p ( y) 2 0 for every y in L. For y in L, let T l ( y )= 0. Then T1is a linear functional on L satisfying T l ( y ) s p ( y ) for every y in L. By Hahn-Banach Theorem 1.5.15, there exists a linear functional T on 8, such that

-

T(Y)= Tl(Y), if Y E L, and

T ( x )s p ( x ) for every x in em. This functional T has the following properties. 1". T(cx + d y ) = c T ( x )+ d T ( y ) for all x, y in emand c and d real numbers. 2". T ( x )2 0 if x = (xl, x 2 , . . .) 2 0, i.e. T is a non-negative linear functional on em.

40

THEORY OF CHARGES

1= (1, 1, 1,. . .). . . .)) = T ( ( x 2 ,x 3 . . .)) for every x = ( X I , x2, . . .) in 8m.

3". T(1)= 1, where

4". T((x1,x2, x3,

5". IT(x)I4 llxllm for every x in fa,i.e. T is a continuous linear functional on em. 6". lim inf,,, x n 5 T ( ( x 1 ,x z , . . . ) ) s l i m Supn+m x , foreveryx = ( X I , X Z , . . .) in em. 7". If x,, n z l is a convergent sequence of real numbers, then T ( ( x 1 ,xz, . . .)) = lim,,, x.,

1" is clear. We prove 2". Note that for any x in 8m, - T ( x ) = T ( - x )5 p ( - x ) = Sup,,l -xn I0 if x = ( x l , x z , . . .) 2 0. Consequently, T ( x )2 0 if x 2 0 . For 3", observe that T ( l ) s p ( l ) =1 and -T(1)= T(-l)< ~(-1) = -1, so that T(1)2 1. Hence T(1)= 1. To prove 4", we proceed as follows. For any x = ( x l , x z , . . .) in em, it can be checked that (xz, x3, . . .) - ( x l , x2, . . .) = (xz-XI, x3-xz, . . .) is in L. Consequently, T((X2,

x3, . . .))-

N X l ,

x z , . . .)) = T ( ( x 2 ,x 3 , . . .) - (x1, xz, = T ( ( X Z - X 1 , Xg-xZ,. = Tl((xZ-xl,

x3-x2,

. .>I *

. .)) * *

a))

= 0.

From this, 4"follows. For 5", we observe the following inequalities.

T ( x ) 5 p ( x ) = S u p x n <SUP IxnI=IIxllm, nzl

nz l

- T ( x ) = T ( - x ) s p ( - x ) = Sup -xn = -1nf x,, nzl

nzl

and

- 1 1 ~ llm = -SUP Ix, I 5 Inf X , tl2l

5T(X)

n z l

for any x = ( x l , x 2 , . . .) in 8,. Hence IT(x)I IIxllm. 6" is a consequence of 4"and the fact that T ( x )s p ( x ) for every x in tm.7" follows from 6". The functional obtained above is called a Banach Limit. One can define a Banach Limit, in abstract terms, as follows. A functional T on 8, is said to be a Banach Limit if T has the properties lo,2", 3" and 4"listed above. One can show that if T has properties lo,2", 3" and 4", then it has properties 5", 6" and 7". Now, we come to the problem of existence of S-invariant charges on S(R). For A c R, let X A E lm be as defined below. (xA),

= 1, if II E A,

=O,

ifn&A,nER.

2.

41

CHARGES

Let T be a Banach Limit on em.Define p on 9 by p (A) = T(xA),A c R. It is clear that p is a probability charge on 9.That, p is S-invariant follows from the observation that for any A c R, XS-'(A)

= ((xA)Z,(xA)3,

.

*)

and that T has property 4", where xA is as defined above.

(9). Banach Limits and General Invariant Charges. Let 9 be a field of subsets of a set R and S a map from R to R such that S-'(A) E 9 whenever A E 9. We show that there exists an S-invariant probability charge p on 9, i.e. p is a probability charge on 9 and p(A) = p(S-'(A)) for every A in 9.Let Y be any probability charge on 9 and T a Banach Limit on em. Define p on 9 by p(A)= T((v(A),v(S-l(A)), .@-'(A)), . . .)) for A in 9. It is clear that p is a probability charge on 9. From 4" of (8), it follows that p is S-invariant. If R = {1,2,3,.. .}, 9=P(R), S the shift transformation on R and v the charge on 9 defined by v(A)=O, if 1 & A ,

= 1 , if l E A , A c R , then the charge p defined above is precisely the S-invariant charge constructed in (8).

(10). Banach Limits and Density Charges. Let R ={l,2,3,. . .} and 9= P(R). A charge p on 9 is said to be a density charge on 9 if lim .u (A) , , = n+m

# ( A n { l , 2 , 3 , .. . ,n } ) n

whenever this limit exists for any set A c R , where for any set B, # B is the number of elements in B. It is obvious that p is positive and p(R) = 1. We show the existence of a density charge. For each n 2 1, let p n on 9be defined by #(An{1,2,3,.. . , n}), AcR. p n (A) = n Then each pn is a probability charge on 9. Let T be a Banach Limit on em.Define p on 9 by E*. (A) = T((PI(N,PZ(A),* * .)),

A = a.

It is clear that p is a probability charge on 9.From 7" of (8), it follows that p is a density charge on P(R).

Now, we introduce the concept of s-boundedness of charges.

42

THEORY OF CHARGES

2.1.4 Definition. Let p be a charge on a field 9 of subsets of a set 52. p is said to be s-bounded if for every sequence A,, n L 1 of pairwise disjoint sets in 9, p (A,) = 0. If p is a real charge, then p is s-bounded if and only if p is bounded. The following results pave the way for the validity of this assertion. 2.1.5 Lemma. Let p be a real charge on a field 9 of subsets of a set 0. If p is unbounded, there exist two sets A1and A2 in $satisfying the following conditions. (i). A l n A 2 = 0. (ii). Ip (A1)IL 1 and lp (A2)12 1. (iii). p is unbounded either on A1 or on A2, i.e. Sup {Ip(B)I; B c A 1 , B E $ } = ~ Oor Sup(Ip(C)I; C c A 2 , C E ~ } = C O .

Proof. Since p is unbounded, there exists B1 in 9 such that lp(Bl)[L Ip(fi)I+1. Then Ip(B;)I =Ip(CR)-p(Bi)ILIIp(CR)I-Ip(Bi)IILIp(Bi)IIp(CR)lL1. It is obvious that p is unbounded either on B1 or on B;. Take A1= Bl and A2= B;, 0 2.1.6 Theorem. Let p be a real but unbounded charge on a field 9 of subsets of a set CR. Then there exists a sequence A,, n L 1 of pairwise disjoint sets in 9 such that 1p (A,)I 2 1for every n 2 1.

Proof. By Lemma 2.1.5, there are two disjoint sets Al and B1 in 9 such that lp(A1)IL 1, )p(B1)l2 1 and p is unbounded on B1. Applying Lemma 2.1.5 again to B1, there are two disjoint sets A2 and B2 contained in B1 such that Ip(A2)1L 1, Ip(B2)1L 1 and p is unbounded on B2. Continuing this way, we obtain a sequence A,, n 2 1 of pairwise disjoint sets in 9such that Ip(A,)I 2 1 for every n 2 1. This completes the proof. 0 An important consequence of this theorem is the following corollary.

Corollary. Let p be a real charge on a field S o f subsets of a set 52. Then p is s-bounded if and only if p is bounded.

2.1.7

Proof. Suppose p is bounded. Let k = Sup {Ip (B)I; B E S}.Then k is finite. We show that Cnzl lp (A,)I I2k for any sequence A,, n 2 1 of pairwise disjoint sets in 9. Let m 2 1 be fixed. Let 11 = (1Ii Im ; p (Ai)2 0) and I2 = (1Ii Im ; p (Ai)< 0). Then

f

i=l

Ip(Ai)I=

c p(Ai)- c p(Ai)

i d 1

i&

2.

CHARGES

43

Hence Xi=, Ip (Ai)]I2k. From this, it follows that lim,,,oc, p (A,,)= 0. So, is s-bounded. Conversely, let p be s-bounded but not bounded. By Theorem 2.1.6, there exists a sequence A,,, n 3 1 of pairwise disjoint sets in 9 such that lp(A,)I 2 1for every n 2 1. Then p (A,) cannot be zero. This contradiction shows that p is bounded. This completes the proof. 0 p

2.1.8 Remark. The assumption that p be real valued in the statement of Corollary 2.1.7 cannot be dropped. As an example, let Q = {1,2,3,. . .} and 9 the finite-cofinite field on R. Let p on 9be defined by p (A)= 0, = CO,

if A is finite, if A is cofinite.

Then p is an s-bounded charge on 9but not bounded.

2.2 THE SPACE OF ALL BOUNDED CHARGES, b a ( i l , 9 ) The object of study in this section is the space of all bounded charges on a field 9’of subsets of a set R. We denote this space by ba(fl,@). There say p Iu if is a natural partial order Ion ba(R,9). For p, u E ba(R, 9), p (F) 5 u(F) for every F in 9. The relation Iis reflexive, antisymmetric The main result of this and transitive. So, Iis a partial order on ba(R, 9). section is that ba(R,9) is a boundedly complete vector lattice. We also introduce a norm 11.I on ba(R, 9) so that (ba(R, 9), I, II-II) becomes a Banach lattice.

2.2.1 Theorem. Let 9be a field of subsets of a set R. Then the following statements are true. (1). If p, u E ba(R, 9)and c, d are real numbers, then c p + du E ba(R, 9). (2). b a ( R , q is a vector space. (3). (ba(R,9), 5)is an ordered vector space, where Iis the partial order on ba(R, 9)introduced above. (4). Let p , u ~ b a ( R , 9 )Define . A on 9 by A(F)=Sup{p(E)+u(F-E); E c F , E E fl,F E9. Then A E ba(R, ( 5 ) . Let p, u E ba(R, 9).Then p v u exisfs irz the partial order Ion ba(fl, 9) and is equal to A defined in (4). (6). L e t p , u ~ b a ( R$, ) . D e f i n e ~ o n 9 b y ~ ( F ) = I{p(E)+u(F-E); nf EcF, EE F E9. Then T E ba(fl,F), (7). Let p , u E ba(R,9). Then p A u exists in the partial order Ion ba(R, 9) and is equal to T defined in (6). I) is a vector lattice. (8). (ba(R, 9),

a.

a,

44

THEORY OF CHARGES

(9). (ba(R, 8, I) is a boundedly complete vector lattice. (10). Forp ~ b a ( f l , 9 )let , llpII=lpl(R). (Recall I p ( = p c + p c -from Section 1.5.) Then 11.I is a norm on ba(fl, 8. (11). (ba(R, 9), I,II. 11) is a Banach lattice.

Proof. (l),( 2 ) and (3) are obvious. (4).It is obvious that A (0) = 0. Since p and v are bounded, A is a bounded function on 9. Let A1 and Az be two disjoint sets in 9. We show that A (Al u A2)= A (Al)+ A (A2).Let B E 9and B c Al u Az. Let Bl = B nA1 and B2= B nA2. Then p (B)

+ v[(Al uAz)-B]

+

= p (B1)+ p (B2) v(Ai -B1)

+ v(Az-Bz)

= [ct (Bi) + v (A1 - BdI + [CL(Bz)+ v(A2 -BdI I A (A,)+ A

(Ad,

as B1c A1,B2c A2 and B1, B2E 9. Taking supremum over all B c Al u A z with B in 9,we obtain A (Al u A2)IA (Al)+ A (A2).On the other hand, let BI, B2E 9, B1 c Al and B2c A2. Then

[II.(B~)+~(AI-B~)I+[CL(BZ)+~(A~-B~)I = p (B1 u Bz) + v [(A1 uA2) - (Bi uBz)] 5 A (A1 uA2). Taking the supremum over all B1c Al with B1E 9 and then supremum we obtain A (A1)+ A (A21IA (A1u A2). Thus over all Bz c Az with B2E 9, A (Al u A2)= A (Al)+ A (A2).Hence A E ba(R, 8. ( 5 ) . It is obvious that p 5 A and v IA. Let $ E ba(R, 9)be such that p 5 $ and v I4. Then for any F in 9,

+

A (F) = SUP{ p (E) v(F- E); E c F, E E 9)

~SU~{$(E)+$(F-E);E~F,EE~) = $03.

So, A I$. Consequently, p v v exists and is equal to A. (6) and (7) can be proved along the same lines as those of (4) and ( 5 ) . (8) is, by now, obvious. (9). Let { p a ;a E r}cba(R, 9) be bounded above, i.e. there exists A E ba(R, 9) such that pa < A for every a in r. We show that Vaorpa exists. Let d be the collection of all finite subsets of r. On d,we introduce a >*) is partial order L* as follows. For C, D ~ dsay, C z*D if C 2 D . (d, a directed set. For each C in d, let pc = VaeCpa. pc, obviously, exists in ba(R, 9)as C is only a finite set. Then the net { p c ;C E d }is an increasing net, i.e. if C, D E & and C ?* D, then p c l p D in ba(R,9). Further, p c s A

2.

45

CHARGES

for every C in d. Let T be the pointwise limit of pc, C E d, i.e. T(F)= limc.dpc(F), F E ~This . limit obviously exists for every F in 9. T is also Since p, 5 T 5 A for any fixed a in r, T is also bounded. It a charge on 9. s)is a boundedly complete is obvious that T = VaErpa. Hence (ba(n, 9), vector lattice. (10). If p = 0, then lp I = 0. So, llpII = 0. Conversely, if IlpII = 0, Ip I(n)= 0. Ipl = 0. Hence p = 0. See Theorem Since 1 ~ is1 a positive charge on 9, 1.5.4(12). If a is any real number and p E ba(R, then llap)I= IapI(C2)= IaIIpI(s2)= IaIIIpII. See Theorem 1.5.4(12). Finally, let pl, p 2 c b a ( a , F ) . Then IIcLI+cL~~I= 1~~1+1l.21(SZ)51p~~1I(R)+\1*.2)(n> =Ilpc~Il+lp211.See Theorem is a norm on ba(R, 9). 1.5.4(12). Hence ((.(( (11). If p, vEba(n, 9)and I p l 5 I v I , then ~ p ~ ( l l ) 5 ~ v Consequently, ~(fl). \\p\Isl\v\\.Hence ba(O,9) is a normed vector lattice. Now, we show that ba(n, 9)is complete under the norm 11 11. Let p n , n I1 be a Cauchy sequence in ba(O,9), i.e. limm,,,+mIIpm-pnll = 0. Since pm- p n s Ipm-pnl for all m,n 1 1 , we have for any F in 9,

m,

-~nl(n)

I ~ m ( F ) - ~ n ( F ) I ~ I ~ m - ~ n I ( F ) ( I ~ m

= llkm - ~ n l l .

This shows that p m(F), m 2 1is a uniform Cauchy sequence of real numbers Let p (F) = limm+mp m(F), F E 9. Thus p m , m 2 1 converges to p over 9. uniformly over 9. p is obviously a charge on 9. Since the convergence is uniform, p is bounded. Since II*(I is a norm, lllp,, -pII-IIpm -pIII 5 II(p,,-p)-(pm-p))II=llpn -pmll,iffollowSthatlimm,, IIpm-pll=O.Hence ( b a ( n , 9 ) , 5,11 * 11) is a Banach lattice. 0 The above theorem in conjunction with Theorem 1.5.4 brings into focus various aspects of bounded charges. Of particular interest, are the charges p c , p - , and lp I associated with p E ba(n, 9). First, we isolate these entities and write formally their computational equivalents. Let p ~ b a ( f l , 9 ) .Then p f = p v O and p - = ( - p ) v O . By Theorem 2.2.1(5),

'(F) = SUP{@(B);B C F ,B E 8, FE and

p-(F) = -1nf

{ p (B); B c F, B E 9}, F EF.

and p - ba(n, ~ and they are called the positive and negative variations of ICL respectively. The charge Ipl = p L c + p -is called the total variation of p. Combining Theorem 1.5.4 and Theorem 2.2.1, we chronicle some salient features of charges in the following theorem for future reference. pc

46

THEORY OF CHARGES

2.2.2 Theorem. Let p E ba(R, 9).Then the following are true. (1). p = p + - p - a n d p + A p - = O . (2). l p l = p + + p - = p + v p - = p v ( - p ) . A n important consequence of this is )(F)= SUP { p (B) - p (F- B); B c F, B E g}, F E 9. (3). I f p = A - v with A, vEba(R,5"), A r O and v 2 0 , then A z p + and

IF

v r p

-

.

Y E ba(R, 9)andA A v = 0 , then A = p + and v = p - . ( 5 ) . p++=$(Ip I + p 1 and p - = $(IP I - p j . + (6). If Y E ba(R, 9)and p Iv, then p 5 v and p - 2 v-. (7). I f v E b a ( R , m and ~ A V = Othen , ( p + v ) + = p + + v + and I p + v l =

(4).I f p = A - v with A,

IPI

+I4

2.2.3 Remark. Theorem 2.2.2( 1) is precisely Jordan Decomposition theorem for bounded charges. Any bounded charge p can be expressed as the difference of two positive charges with a certain minimality property in the following sense. If p = A - v also, where A, v 2 0, then A L p + and v 2 p -. We will take up the issue of writing a given charge as a difference of two positive charges in Section 2.5. In the following theorem, we give an alternative description of lpl, in addition to the one described in Theorem 2.2.2(2).

2.2.4 Theorem. Let p E ba(R, 9).Then for any F in 9, i=l

where the supremum is taken ouer all finite partitions F1, Fz, . . . ,F, of F in 9.Further, IpI(R)52 S u p { l p ( F ) I ; F ~ 9 } . Proof. Let F1,F2,. . . ,F, be any partition of F in 9. Let I = (1 5 i 5 n ; p(Fi)L 0) and J = (1Ii ~ np(Fi) ;
i

i=l

Ip(Fi)I=

c p (Fi) - Ci s J p(Fi)

is1

5 IF I(F),

xr=l

by Theorem 2.2.2(2). Consequently, Sup (p(Fi)(IIp ((F),where the supremum is taken as described above. On the other hand, let B E 9 and

2.

47

CHARGES

B c F . Then {B,F-B} is a partition of F in 9 and p ( B ) - p ( F - B ) s Ip(B)I + Ip(F-B)I 5 Sup Z;=l )p(Fi)l, where the supremum is taken as described above. Therefore, \ pI(F) = Sup { p (B) - p (F - B); B c F, B E 9) 5 SupC:=, Ip(Fi)l. This completes the proof. 0

2.3 MEASURES In this section, we introduce measures and establish some properties of measures. We also give a set of necessary and sufficient conditions under which a charge is a measure.

2.3.1 Definition. Let 9 be a field of subsets of a set a. A measure on 9is any map p from 9 to [-a, a]having the following properties. (i). p ( 0 ) = 0 . (ii). If F,, n 2 1 is a sequence of pairwise disjoint sets in 9 with UnzlF, in 9,then p(

gl 2l Fn)

=

p (Fn)*

Any measure is, obviously, a charge. If p is real valued, we call p a real measure. If p is bounded on 9,we call p a bounded measure. If p 2 0 , we call p a positive measure.

2.3.2 Proposition. Let p be a charge on a field 9of subsets of a set SZ. Then the following statements are true. (1). p is a measure on 9if and only if limn+mp (A,) = p (A) whenever A,, n 2 1 is an increasing sequence of sets in 9with A = UnzlA, in 9. (2). Let p be real. The following are equivalent. (i). p is a measure on 9. (ii). p (A,) = p(A) whenever A,,, n 2 1 is a decreasing sequence of sets in 9with A, = A in 9. (iii). limn-,m p (A,) = 0 whenever A,, n 2 1 is a decreasing sequence of sets in 9with A, = 0.

nnrl

n,,,

Proof. (1).Suppose p is a measure on 9. Let A,, n 2 1 be an increasing sequence of sets in 9 with A = U n Z 1A,, in 9.Let B l = A l , B2= A2 - Al, . . . ,B, = A, - A,-I, . . . . Then B,, n 2 1is a sequence of pairwise disjoint sets in 9 and

U An= nUr l Bn.

n z l

THEORY OF CHARGES

u An)=p( u Bn)

I*.(A)=~( n z l

n r l

m

=

C p ( B n ) =mlim C p(Bn) nzl +m n = l

The converse is simple to prove. ( 2 ) . (i)+(ii). Let A,,, n 2 1 be a decreasing sequence of sets in 9 with A, = A in 9. Then A:, n 2 1 is an increasing sequence of sets in 9 with UnZlA:=AC. Let B1=AE, B2=A;-Ai,.. . , B,=A',-A:-l, .... Then B,, n 2 1 is a sequence of pairwise disjoint sets in 9with

nnzl

u B, u A:. =

nzl

nzl

Consequently,

= lim p (A:) = lim [ p (a)- p (A,)]. n+m

n+W

Hence p (A,) = p (A). ( i i ) j (iii). This is obvious. (iii)=$ (i). Let B,, n 2 1 be a sequence of pairwise disjoint sets in 9 such that UnrlB, E 9. Let A, Bm,n 2 1. Then A,, n 2 1 is a decreasing sequence of sets in 9with A, = 0.Therefore,

=urn,, n,,,

O = lirn @(A,)= n+m

Hence

Note that Theorem 2.3.2(2)is not valid if p is not real.

m=l

2.

49

CHARGES

We now give a useful sufficient condition under which a charge is a measure. We begin with a definition.

2.3.3 Definition. A collection V of subsets of a set R is called a compact class if it has the following property: if C,, n 2 1 is a sequence of sets in V with C, = 0, then there exists m 2 1such that C, = 0.

n,,,

n:=:=,

2.3.4 Theorem. Let 9be a field of subsets of a set R and V a compact class contained in 9. Let p be a positive bounded charge on 9having the following approximation property : p (F)=Sup &(C);

C C F, C EU},F E9.

Then p is a measure on 9. Proof. In view of Proposition 2.3.2(2), it suffices to show that limn+mp (A,) = 0 for any decreasing sequence A,, n 2 1 of sets in 9 with A, = 0.Let E > 0. For each n 2 1,there exists C, in V,C, c A, such A, = 0, C, = 0. So, there that p (A,) 5 p (C,) + &/2".Since C, = 0. Consequently, exists rn 2 1 such that

n,,

n,"=,

fi

b(Am)=p(n = l An) m

5

nnrl

n,,,

CJ(An-cn))

C P (n = l

m

C p(An-Cn)= nC= l [ ~ L A n ) - ~ ( c n ) l < & . n=l

So, for every n 2 m, p (A,) < E . Hence

I.L (A,) = 0.

2.3.5 Examples (1). Let R be any infinite set and 9 the finite-cofinite field on R. Let on 9be defined by p (A) = 0, if A is finite, = 1, if A is cofinite.

p

If R is countable, then p is a charge on B but not a measure. If R is uncountable, then p is a measure on 9. In fact, in this case, every charge on 9 is a measure. (2). A standard example of a measure is the Lebesgue measure A on the Bore1 cT-field 9 of the real line R. This is the measure on 94 such that A{(a,b ) } =b - a for every -m
50

THEORY OF CHARGES

2.4 THE SPACE OF ALL BOUNDED MEASURES, c a ( i 2 , m

In this section, we take up the study of the space c a ( R , 9 ) of all bounded measures on a field 9 of subsets of a set R. The main result of is a normal vector sublattice of ba(R, 9). First, this section is that ca(R, 9) we need a proposition. + 2.4.1 Proposition. Let p, v E ca(R, 9).Then p ,p , lp I, p v v and p A v E ca(R, 9). Proof. First, we show that p + is a measure. Let A,,, n 2 1 be a sequence of pairwise disjoint sets in 9such that UnrlA,, E g. Let B c UnZl A,, and Let B, = B nA,,, n 2 1. Then B E 9.

u B n ) = C CL(B,ASC II.+(A,,).

~(B)=P(

n2l

n2l

nz1

Taking supremum over all BE^ with BcU,,,lA,,, we obtain p ~ ( ~ , , l A , ) ~ ~ , , l p ~ ( Since A , ) . p + is a positive charge on 9, Cnzl p+(A,,)%@+(Unz1 A,,). See Proposition 2.1.2(viii). Hence A,) =Inzl p+(A,,).Thus p + ca(R, ~ 9). By a similar argument, we can show that p - ~ c a ( R .F). , So, I p ) = p + + p - ~ c a ( Rq. , Now, we show that p v v and p A v are measures. By Proposition 2.3.2(2), it suffices ( p A v)(A,,) whenever A,, to show that limm-too( p v v ) ( A , ) = 0 = n 2 1is a decreasing sequence of sets in 9with A,, = 0.By Theorem 1.5.4(14),

p+(unz1

n,,,,

-IpI-IvI

Sp

A

v

I@ V v Ipl f l v l .

, E c a ( R , 9 ) , we have ( p/(A,,)= 0 = limn-toolv((A,,).From Since ( p ( (vI this, it follows that the desired limits above are each equal to zero. Hence 0 p v v and p A v are measures.

2.4.2 Theorem. ca(R, 9) is a normal vector sublattice of ba(R, 9).In particular, ca(R, 9)is a closed subspace of ba(R, 9). Proof. By Proposition 2.4.1, it follows that ca(R, 9) is a vector sublattice We now show that it is normal. Let p ~ c a ( R9) , and v E of ba(R, 9). ba(R, 9be )such that 0 5 1v1s Ip 1. Since /pi is a measure and (v(F)I5 lv((F) v is a measure by Proposition 2.3.2(2). Hence Y E ca(R,9). for every Fin 9, be such that V a o rpa exists in ba(R, 9). Let Let { p a ;a E r}c ca(R, 9) 7 = V a E pa. r We show that T E ca(R, 9). Let d be the collection of all finite subsets of r. For C, D in d,say C ?* D if C 3 D . For C in d, let pc= VaeC pa. Then pc, C E is ~an increasing net of measures whose pointwise limit is T, i.e. T(F)= lim pc(F), F E9. CE sp

2.

51

CHARGES

See the proof of Theorem 2.2.119). We show that r is a measure. Since V a s rpa = VCEd pc = r , let us assume that r itself is a directed set and pa, a E r is an increasing net of measures. Let d = SUpasr p,(R). Since p, 5 T for every a in r, d < co. Let a,,,n 2 1 be a sequence in r such that pUn(fl) = d . We can assume, without loss of generality, that pa, 5 p m 2 5* * . Let r*(F)= p,,(F), F E9. We show that r * is a measure on 9. T* is obviously a bounded charge on 9. Let A,, n 2 1be any increasing sequence of sets in 9with UnzlA, = A E 9. In view of Proposition 2.3.2(1), it suffices t o show that limk,, r*(Ak) = T*(A). A t this juncture we assume that each pa is a positive measure. Note that

-

lim T*(Ak) = SUP 7*(&) k-m

= SUP SUP p,,(Ak)

k z l

k z l nzl

= s u p s u p p,,(Ak) = s u p p,,(A) = r*(A). n z l k z l

nz1

This shows that 7* is a measure on 9. Next, we claim that r * = r . Let a in r be arbitrary. We show that pa s'r*. Note that Pa v r * = Pa v

(Ll

P%) =

v

nzl

(Pa v Fan).

If ( p , v ~*)(n) > d , then (pa v pa,)(fl)> d for some n 2 1. This contradicts the definition of d . So, (pa v r * ) ( f l )5 d = r * ( f l )5 (pa v ~*)(fl).So, (pa v ~ * ) ( f = l )r*(fl).Since r * s p a v r * and ~ * ( f l=) (pa v r*)(fl),it follows that T* = p, v r * ! (Check this.) This implies that pa ST*. Since this is true for every a in r, V a E pol r = r 5 r * . On the other hand, since pan:s r for pan= T* 5 T. Hence T = r * . This shows that r is ameasure. every n 2 1, Vn2? In the above, we have shown that r is a measure under the assumption that each p, is a positive measure. Now, we treat the general case. Choose and fix a0 in r. Let v, = polv p,, + Ipa0l,a E r. Each Y, is a positive measure since I/, 2 pa0+ Ip,,l = 2pL0 2 0. Observe also that

v

I/,

=

a E r

v

[(Pa v

+l ~ ~ , I l

11.010)

,Er

by Theorem 1.5.4(1)

By what we have proved above, r+lp,,l is a measure. Since (paOlis a is a normal sublattice measure, it follows that 7 is a measure. Hence ca(R, 9) of ba(fl, It follows from Theorem 1.5.19 that c a ( f l , 9 ) is a closed sublattice of bdfl, 0

a.

w.

52

THEORY OF CHARGES

2.4.3 Corollary. ca(R, 9 )is a boundedly complete vector lattice and also a Banach lattice in the usual norm. 2.4.4 Remark. Given any field 9 of subsets of a set R, one can find a set X and a c+-field d on X such that ba(Q, 9) and ca(X, d)are isometrically isomorphic as Banach lattices, i.e. there is a linear map T from ba(R, 9 ) onto ca(X, d)such that IIT(p)ll=llpll, p E ba(R, 9) and T ( p )1 0 whenever p 2 0 . This can be proved using the Stone Representation theorem for Boolean algebras given in Section 1.4.

2.5 JORDAN DECOMPOSITION THEOREM Jordan Decomposition theorem for bounded charges has been discussed in Remark 2.2.3. It essentially says that every bounded charge can be written as a difference of two positive charges in a minimal way. The main theorem of this section gives a simple necessary and sufficient condition for such a decomposition to prevail for charges not necessarily bounded. First, we introduce the lattice operations v and A for general charges.

2.5.1 Definitions. Let p and v be two charges on a field 9 of subsets of a set R such that either both p and v avoid the value -a or both avoid the value +a.Define the set functions A and T on 9 by

+

A (F)= SUP{ p (E) v(F-E); E c F, E E

a,

FE9,

and T(F)= Inf { p (E)+ v(F- E); E c F, E E 9}, F E9. The above set functions were defined for bounded charges in Theorem 2.2.1(4) and (6).We used the same formula for general charges in the above definition. We denote A by p v v and T by p A v. This is consistent with the notation used for bounded charges.

2.5.2 Proposition. Let p and v be two charges on a field 9of subsets of a set Q such that either both p and v avoid the value -a or both avoid the value +a.Then the set functions A ( = p v v ) and T ( = p A v ) defined above are charges on.9. Proof. The proof given for Theorem 2.2.1(4) and (6) carries through essen0 tially here. The following theorem is the main result of this section.

2. 2.5.3

of a set

53

CHARGES

General Jordan Decomposition Theorem. Let 9 b e a field of subsets n. Let p be a charge on 9.Define p + and p - by p+(F)= Sup { p (E);E c F, E E9}, F E g,

and y-(F) = -1nf {p(E);E c F, E E

w,

F E 9.

Then the following statements are true. (1). p + and p - are positive charges on $. (2). I f p does not take the value +a,then p + - p = p - . (3). If p does not take the value -00, then p + p - = p c . (4). I f p does not take the value +OO and ~ 1 p- = p 2 for some positive c h a r g e s p l , p 2 0 n 9 ,t h e n p ~ ~ p + a n d p ~ ? p - - . ( 5 ) . I f p does not take the value --CO and p + hl = A 2 for some positive charges h l , h2 on 9,then h 1 z p - and h 2 ? p C . (6). p = p + - p - if and only if p is either bounded below or bounded above. More generally, we can write p = p l - p 2 for some positive charges p l , p2 on 9 if and only i f p is either bounded below or bounded above. (7). p + A p - = 0 if and only if p is either bounded below or bounded above. ( 8 ) . I f pl and p 2 are positive charges on 9 satisfying p = p l - p 2 and pI ~ p 2 = 0 then , p~ = p+ and p2 = p - . (9). If p is a real charge, then p = p + - p - holds if and only if p is bounded. In such a case, both p + and p - are bounded. More generally, i f p is a real charge, then we can write p = p1 - p 2 for some positive charges p l and p2 on 9 if and only if p is bounded. Proof. (1)follows from Proposition 2.5.2 if we observe that p + = p v 0 and p - = ( - p ) v 0 as per Definition 2.5.1. (2). Let F E $. Suppose p(F) = -a.Then, from the definition of p - , p-(F) = co.So, p+(F)- p (F)= a = p-(F). Suppose p (F)> -a.By the given hypothesis, -a< p (F)< a.Consequently, --CO < p (E) < 00 for any E in 9 such that E c F . See Proposition 2.1.2(vii). So, CL +(F)- W

(F)= SUP{ P

(a;E c F, E

= SUP{ p (E)- p

E

SI(F)~

(F);E c F, E E $}

=SU~{-~(F-E);ECF,EEF} = -1nf {p(C);C c F, C E = p-(F).

This completes the proof. (3). This can be proved as above.

54

THEORY OF CHARGES

(4).Since p l - p = p 2 and p 1 and p2 are positive, it follows that p l z p . So, for any F in 9, p+(F)=Sup{p(E);E c F , E ~ 9 } s p ~ ( FHence ). p+5 p1. For the second part, observe that p + - p s p l - p = p 2 .By (2), p + - p = p . This completes the proof. ( 5 ) . The proof is analogous to that of (4). (6). Suppose p is bounded above. By (2), p + - p = p - . Note that pLfis a bounded charge. Consequently, - p = p - - p + or p = p + - p - . A similar argument works when p is bounded below. Conversely, if p = p + - p - , then either pLcis bounded or p - is bounded. In the former case, p is bounded above and in the later case, p is bounded below. The more general version can be established using (4). (7). Suppose p is bounded below. We show that p + A p - = 0. Since p is bounded below, p - is a positive bounded charge. So, for any F in 9, +I(

A

p-)(F) = Inf {p+(E)+p-(F-E); E c F, E E fl

+

= Inf { p (E) p-(E) +p-(F-E); E c F, E E 9},

(by (3)) =Inf{p(E)+p-(F); E c F , E € . F } = Inf { p (E); E c F, E E -+p-(F),

(since p - is bounded) = -p-(F)+p-(F)=O.

If

is bounded above, a similar argument shows that p + A p - = 0. Conversely, suppose p is neither bounded below nor bounded above. We show that p+r\ p - # O . Since p cannot take both the values +a and -a,assume, without loss of generality, that p does not take the value -a.Note that pL-(n) = a.By (3), p + p - = p + . So, p

( F +A

p - ) m = u p + p - > A p-l(n2) = Inf { ( p +p-)(F)+p-(F");

FE9}

= Inf {p(F)+p-(R); F E 5F)= a.

This completes the proof. (8). If p = p1 - p ~ where , p l and p2 are positive charges, then p is either bounded below or bounded above. See ( 6 ) .Assume p is bounded above. This implies that p l is a bounded charge. Since p = p l - p 2 = p + - p -, p1-p:-p2=-p-50. Therefore, p 1 - p + 5 p 2 . By (4),p l ? p + . So, 0 5 p1-p +5p2. Since p l ~ p ~ =and O O s p l - p c s p l , it follows that 0 s (PI - p ) 5 p1 A p2 = 0. Hence p l= p + . The other equality follows easily now.

2.

55

CHARGES

(9). If p is a real charge and p = p1- p 2 , where p 1 and p2 are positive charges, then p 1 and p2 are bounded. So, p is bounded. If p is bounded, of course, we can write p as a difference of two positive charges. This completes the proof of the theorem. 0 Some comments are in order on the above theorem.

2.5.4 Remarks. (i). The charge p described in Example 2.1.3(2) is neither bounded above nor bounded below. There is no way we can write p as a difference of two positive charges. For this charge, p + - p = p - and p f p - = p + . p + and p - work out as follows. p +(A)= n, = 03,

p-(A) = 0, = 03,

if A is finite and has n elements, if A is cofinite. if A is finite, if A is cofinite.

= 03. Observe also that (p’ A &*.-)(a) (ii). Theorem 2.5.3 goes through in toto if we replace the word “charge” by “measure”.

An interesting result emerges for measures on a-fields in contrast to the Remark 2.5.4(i), i.e. every measure on a a-field can be written as a difference of two positive measures. First, we need a lemma.

2.5.5 Lemma. Let p be a measure on a u-field % of subsets of a set R. Then p is either bounded below or bounded above. Proof. First, assume that p is real valued. In this case, we show that p is bounded. Suppose p is unbounded. By Theorem 2.1.6, there exists a sequence B,, n 2 1 of pairwise disjoint sets in % such that Ip (Bi)l r 1 for every i 2 1. Then, either there exists a sequence n1 < n2 < * * such that p (B,,) 2 1 for every i L 1 or there exists a sequence k l< k2 < such that p ( B k l ) % - l for every i r l . Assume that the former holds. Then p(UiZ1 B,,) = 03 contradicting the fact that p is real valued. If the latter holds, we do still get a contradiction. Hence, if p is a real valued measure, then it is bounded. 031 or in In the general case, observe that p takes values either in (-a, [-a, 03). Assume that p takes values in (-O3,03]. Then we show that p is bounded below. Suppose p is unbounded below. We find A1 in % such that p (A1) 5 -1. Since p is real valued on A1 n%, by what we have proved above, p is bounded on Al. Consequently, p is unbounded below on A?. So, we can find A2 in 2l such that A2 c A; and p (A2)I-1. By the same reasoning given above, we can show that p is unbounded below on Af - A2.

--

56

THEORY OF CHARGES \

Continuing this way, we obtain a sequence A,,, n 2 1 of pairwise disjoint A,,) = -a.This sets in % such that p (A,) 5 -1 for every n 2 1. So, p (UnZl is acontradiction. Hence p is bounded below. This completes the proof. 0

2.5.6 Jordan Decomposition Theorem for Measures on a-fields. Let be a measure on a u-field % of subsets of a set R. Then we can write f

F=P

p

-

-cL

with the property that p + A p - = 0. Further, the above decomposition has the following optima& property: if p = p l- p 2 , where p I and p2 are positive measures on %, then p 1 2 p + and p2 L p -. Proof. By Lemma 2.5.5, p is either bounded below or bounded above. Remark 2.5.4(ii) completes the proof. 0 2.5.7 Remark. The above theorem is not valid for charges on a-fields.

2.6 HAHN DECOMPOSITION THEOREM In this section, we prove Hahn Decomposition theorem for charges. Hahn Decomposition theorem for measures on a-fields will be proved in Section 6.1.

2.6.1 Definition. Let 9 be a field of subsets of a set R and p a charge on 5 Let E > 0. A partition {D, D? of s1 with D in 9is said to be a E-Hahn decomposition of p if the following are satisfied.

+p (B) C c D" +p (C)

B E 9, B c D C E 9,

5 E. 2 -E.

2.6.2 Hahn Decomposition Theorem for Charges. Let p be a charge on a field 9of subsets of a set R which is either bounded below or bounded above. Then for any E >0, there exists a E-Hahn decomposition for p. I f p is neither bounded below nor bounded above, there exists E > O for which there is no E-Hahn decomposition of p . Proof. We give a direct proof of this result. This can also be proved using Jordan Decomposition theorem. Assume that p is bounded below. Let d = Inf (r-L (A); A E 9). Then d is a finite number. Let E > 0. We can find D in 9 such that d 5 p (D) Id + E . This implies that -CO < p (D) < co and for any B in 9,B c D , we have -oo
2.

-

CHARGES

57

The statement that p admits E-Hahn decomposition for every E > O is equivalent t o the statement that p i h p - = 0. But this is equivalent to the statement that p is either bounded below or bounded above by Theorem 2.5.3(7). This proves the second part of the thereom. 0

2.6.3 Remark. Exact Hahn-decomposition, i.e. E-Hahn decomposition for E = 0, need not exist for every charge. For example, let R = { 1 , 2 , 3 , . . .}, 9the finite-cofinite field on R and p(A)=

1

(-1)"/2",

Ae9.

noA

There is no set D in 9 such that p ( B ) s O for every B in 9, B c D and p (C) 2 0 for every C in 9, C c D'.

CHAPTER 3

Extensions of Charges

One way of obtaining charges on a given field 9 of subsets of a set SZ is to look at subcollections % of 9and set functions v defined already on %? and see if v can be extended to 9 as a charge. For example, if v is a we can extend u from %? 0-1 valued charge on a given sub-field % of 9, to 9 as a 0-1 valued charge. The underlying theme of this chapter is to seek extensions in the spirit of the above example. In Section 3.1, we associate a natural functional T on a suitable vector space with a given set function u on a given class % of sets and study the interplay between u and T. In Section 3.2, we introduce the notion of a real partial charge on a collection %' of sets contained in 9and show that these are precisely the set functions on % for which extensions are possible. In Section 3.3, we study the extension procedure developed by Los and Marczewski. Miscellaneous useful extensions are dealt with in Section 3.5. Finally, in Section 3.6, we look for a common extension to 9 of two set functions defined respectively on two classes of sets %' and 9 contained in 9.

3.1 REAL VALUED SET FUNCTIONS AND INDUCED FUNCTIONALS Any real valued function p on a given class 9 of subsets of a set SZ, under certain conditions, gives rise to a natural linear functional on a suitable vector space. We study this correspondence in this section.

3.1.1 Definition. Let 9 be a collection of subsets of a set 0. Let

B(9)={f:SZ+R;f=

i=l

riIAiforsomeAl,A2, ..., A,

in 9, rl, r2, . . . ,r, rational numbers, It is obvious that numbers.

/

I

II 2 1

.

B(9)is a linear space over the field of all rational

3.

59

EXTENSIONS OF CHARGES

3.1.2 Definition. Let 9 be a collection of subsets of a set R and p a real valued function on 9.We set

for A1,A2, . . . , A, in 9, r l , r2, . . . ,r, rationals and n 2 1. We study the interplay between p and T. First of all, we examine the unambiguity of the definition of T. More precisely, if CF=l riIAi=, :I sJBj for some A1, Az, . . . ,A,, B1, Bz, . . . ,Bm in 9, r l , r 2 , . . . , rn, s1, SZ, . . . , Sm rationals, is Cysl rip (Ai)= C ,:, sjp(Bj)? If T is well defined, we call T the induced by p. The following proposition provides an functional on 2(9) answer to the above question.

3.1.3

Proposition. T is well defined if and only if n

m

i=l

j=l

c p ( A i ) = C p(Bj)

holds for any two finite sequences A1, A2,. . . , A,, and BI, Bz, . . . , Bm of not necessarily distinct sets from 9satisfying m

n

C i=l

C IB~.

=

j=l

Proof. In order to show that T is well defined, we have to establish k

f

C rip(Ci)= C sjp(Dj)

i=l

j=l

whenever k

C i=l

f

dci=

C

SjIDj

j=l

for C1, C 2 , . . . ,c k , D1, D 2 , .. . ,D, in 9 and r l , r2,. . . , r k , s1, SZ, . . . ,s, rationals, Since ri, r2, . .. ,rk, sl,s2,, . .,sc are rationals, we can rewrite the equality k i=l

k

I

riIci= j=l

f

miIci =

sjIDj as i=l

njIDi j=l

by cancelling the common denominator of all the given rationals leading to the situation that m l , m z , . . . , mk, n1, n2,. . . , n, are integers. This later equality can be rewritten in the form n

m

60

THEORY OF CHARGES

Retracing these steps from m

n

C p(Ai)=jC p(Bj), i=l =1 we obtain k

f

C rip(Ci) = j C= l sjp(Dj)i=l 0

The converse is trivial.

Thus, if T is well defined on the linear space 2'(.F),then it is a linear functional on 2'(9). Now, we aim to show that T is a well defined linear functional on 2(9) when 9is a field of subsets of a set and p a real charge on g.Moreover, there is a one-to-one and onto correspondence between linear functionals and ) real valued charges on 9.For this, we need on the linear space 2'(9 the following results. (For sets C1, Cz, . . . ,C, and k > n, we use the convenCii = 0.) tion that

ulsil
3.1.4 Lemma. For any two finite sequences Al, Az,. . . , A, and B1, Bz, . . . , B, of sets, the following statements are true. (a). IA, SC,:, I B ,if and onZy if

zy=l

k

k

U lsi1
n Aii c

j=l

U l s i l
n Bi,

s m j =1

for every 1 I k 5 n. IAi = II B , if, and : , only if (b).

for every 1 I k 5 max {m, n}. Moreover, one can always write

ck=lzsil
Cy=l IAi = Cyzl Ic,, where k


Proof. It is obvious that and only if

0A,, j 1

lsksn.

=

zye1IA,(w)?k, where k is a positive integer, if 6JE

u

k

n Aij.

1si 1
From this, (a) follows. (b) is a simple consequence of (a).

3.

To prove the last part, we note that C1=) C2 =) * k

1s11

U < i2<.

* =)

n A,.

1s i I < i Z < . . . < i k

s n j=1

Cn and k

u

n c,=ck=


61

EXTENSIONS OF CHARGES

0

s n j=1

Recall that a collection 9 of subsets of a set R is said to be a lattice if A u B and A n B E 9 whenever A, B E 9. If 9 is a lattice of subsets of a set R, then a real valued function p on 9 is said to be a real modular function on 9 if p (A)+ p (B) = p (A u B) + p ( A n B) for every A, B in 9.

3.1.5 Proposition. Let 9 be a lattice of subsets of a set R and p a real modular function on 9. Then for any finite number of sets A1, AZ, . . . , A, from 9, we have

In particular, if 9 is a field and p a real charge on 9,the above assertion is true. Proof. The proof given for Proposition 2.1.2(x) is a proof exactly for this assertion. 0 The following theorem shows that T is well defined in some special cases.

3.1.6 Theorem. (f). Let 9 b e a lattice of subsets of a set R with 0 in 9'. Let p be a strongly additive real function on 9, i.e. p is a real modular function on 9 satisfying the condition that p ( 0 ) = 0. Then the induced functional T o n 9(9) is well defined. (2). Let 9 be a field of subsets of a set R and p a real charge on 9. Then the induced functional T o n is defined unambiguously.

9(m

Proof. (1). In view of Proposition 3.1.3, it suffices to prove that IAi = Ci"=,I B i for A1,Az, . . . ,An, p (Ai) p ( B j ) whenever BI, Bz, . . . ,Bm in 9.By Proposition 3.1.5,

=xi"=,

f p(Ai)= f

U

P(

k=l

i=l

?IAij)

lsil
j=l

and m

C j=1 Since

p(Bj)=

xyzlIAAi=I,?,

IBj,

1 s il

f

k=l

U
P(

6Bii)*

U. . < i k s m j = l

lsil
by Lemma 3.1.4(b), k

nA, =

ik s n j = 1

U

1s i 1
k

n Bij

s m j =1

62

THEORY OF CHARGES

for every 1Ik 5 max {m,n}. Assume, without loss of generality, that m If rn < k 5 n, it is obvious that

5 n.

k

n Aij= 0.

U

l s i l
Since p is a strongly additive real function on 9, it follows that

? p(Ai)= !?P( k=l

i=l

U

lsil
AAij)+ k = m + l

j=l

~(0)

m

=

c I*(Bk)*

k=l

This proves (1).(2) is a special case of (1).

0

The following theorem looks at the converse implication of the above theorem. (

Theorem. For a given collection 9of subsets of a set 0, let T be a linear functional defined on the linear space S(9) over the field of rational numbers. For A in 9, set p(A) = T ( I A ) . Then the following statements are true. (1). If 9is a field of subsets of 0, p is a real charge on 3. (2). If 9 is a lattice on R, p is a real modular function on 9. (3). If $is an arbitrary class of subsets of SZ, the set function p on Fsatisfies p(Bj) whenever I A= ~ the following condition : I:=,p (Ai)= CJtlIB,for Al, A*, . . ,A,, B1, B2,. . . ,B, in 9.

3.1.7

c,:,

Proof. We prove (2). Let A, B E 9. Since IA+IB = I A u B +IA,B, we have /.L(A)+El.(B)= T(IA)+T(IB)=T(IA+IB)=T(IA"B +IAnB) = T(IA"B

+ T ( I A ~ B=)p (A uB) + P (A n B ) .

Hence p is a real modular function on 9. Note that if 0 ~ 3 , then p ( 0 ) = T(Iar)=T(0)=O.Now (1) is a special case of (2). (3). This is obvious. 0

3.1.8 Corollary. (1). Let 9 be a lattice of subsets of a set SZ such that 0 E 9. Then there is a one-to-one and onto correspondence between the collection of all strongly additive real functions on 9and linear functionals on LE'(9). (2). Let 9be a field of subsets of a set SZ. Then there is a one-to-one and onto correspondence between the collection of all real charges on S a n d linear functionals on Z(9). 0

3.

63

EXTENSIONS OF CHARGES

Now, we look at the relationship between positive bounded charges p on a field 9 of subsets of a set R and the induced linear functionals T on

m?.

3.1.9 Theorem. Let 9be any collection of subsets of a set R and p a real valued function on 9. Let T be defined on 2?(.9) as in Definition 3.1.2. Consider the following statements. (a). p is positive. (b). C;=l p (Ai)2 C,:, p(Bj) whenever I A i zCLl I B i for A l , Az, . . . , A,,, B1, Bz, . . . , B, in 9. (c). T is well defined and T(f ) 2 0 whenever f ~2’(9) and f 5 0. Then the following statements are true. (i). (b) and (c) are equivalent. (ii). (6) implies (a). (iii). ( a ) , ( b ) and (c) are equivalent if 9is a field on R and p a charge on 9. Proof. (i). Suppose (b) holds. By Proposition 3.1.3, T is well defined. Let a n d f r O . T h e n f = x i k _ l r i I c i f o r s o m e C 1 , C z , ..., Ck i n 9 a n d r l , r2, . . . ,rk rationals. Writing ri = mJm, i = 1 ,2 , . . . , k, where m l , m 4 . . .,mk are integers and m a positive integer, we observe that mf = Ci=lmiIci.We can rewrite this equality as mf = lai-I;=, I B i with Ai’s and Bis coming from {Cl, Cz, . . . , C,} and p, q z 1. (Why?) If f LO, I A ?I;=, ~ I B j . Since (b) holds, @(A;)?I;=,p(Bj). Conthen sequently,

fEz(9)

xy=l

xr=l

T(mf) = mT(f) = T( P

=

f

i=l

IAi

-

5

IBj)

j=l

q

C @(Ai)- C p(Bj)LO.

i=l

j=l

This proves (c). If (c) holds, it is obvious that (b) holds. (ii). Let A E 9.Then IA+IA 2 IA. Consequently, p (A) + p (A) 2 p (A) which implies that p (A) 2 0. (iii). Using Lemma 3.1.4(a), Proposition 3.1.5 and the monotonicity of the positive charge p on the field 9, one can show that (b) holds whenever (a) holds. Thus (a), (b) and (c) are equivalent when 9is a field on $2. 0

Remark. The implication (a)+ (b) is not valid if 9 is a lattice on R, 0 E 9and p a strongly additive real function on 9. Here is an example. Let R={1, 2,3} and 9 = { 0 , { 1 } , {1,2},{1,2,3}}. 9 is a lattice on R. Any function p on 9is a modular function. One can take the following function 3.1.10

o n 9 . p ( 0 ) = 0 , p ( { l } ) = l , p({1,2})=$andp({1,2,3})=$. T h e n p is a positive strongly additive real function on 9.For this p , (b) of Theorem 3.1.9 fails to hold, even though the associated functional is well defined.

p

64

THEORY OF CHARGES

3.2 REAL PARTIAL CHARGES AND THEIR EXTENSIONS In this section, we show that under some natural conditions we can extend a real valued set function on a collection V of subsets of a set R to any field 9on R containing V,as a charge.

3.2.1 Definition. Let V be a collection of subsets of a set R. A real valued p(Bj) function p on V is called a real partial charge if CrXlp (Ai)= whenever I:=,I A j=IJ:,I B for ~ A1, A 2 , .. . , A,,, B1, B 2 , . . . , B, in V,i.e. the functional T defined on 9(V)is well defined. 3.2.2 Definition. Let V be a collection of subsets of a set R and p a positive real valued function on V. p is said to be a positive real partial p(Ai)lCT=lp(Bj) whenever l a i ICY=, IB, for charge if I:='=, Al, AZ,. . . ,A,, B1,B z , . . . ,B, in V.

zrZl

If p is a real partial charge on V and p(C)?O for every C in V,it does not follow necessarily that p is a positive real partial charge on V. If V is a field or a ring of sets on R, then a real valued function on %' is a real partial charge on V if and only if it is a real charge on V.If V is a lattice on R with 0 in V, then a real valued function on V is a real partial charge on V if and only if it is strongly additive. The following proposition demonstrates that for the extension problem of charges, the given set function has to be at least a partial charge.

3.2.3 Proposition. (a). Let p be a real charge on a field 9of subsets of a set R. Let V c 9. Then the restriction fi of p to V is a real partial charge on V. (b). Let p be a positive bounded charge on a field 9of subsets of a set R. Let V c 9. Then the restriction fi of p to V is a positive real partial charge on V. Proof. (a) is a consequence of Proposition 3.1.3 and Theorem 3.1.6(2). 0 (b) is a consequence of Theorem 3.1.9(iii). Now, we come to the extension problem for charges.

3.2.4 Theorem. Let p be a real partial charge on a collection %' of subsets of a set R. Let A c R be such that A &V. Then there exists a real partial charge fi on V u{A} which is an extension of p from V to V v {A}. Proof. Let T be the linear functional on 2 ( V ) induced by p on V. If I A E ~ ( V define ), @(A)= T(IA).If I A @ Y ( V )set , fi(A)= any arbitrary but fixed real number. For C in V,set f i ( C )= p ( C ) . Now, we claim that El. is a real partial charge on V u {A}. It is obvious that fi is an extension of p from V to V u {A}.

3.

EXTENSIONS OF CHARGES

65

If I A E 2'(%'), then 2'(%u {A}) = 2'(%'). Consequently, the map T :9(% u {A})+ R is well defined and the set function fi on %' u {A} defined by fi(B)= T(IB) for B in %' u {A} is a real partial charge on %' u {A}. See Theorem 3.1.7(3). fi is the desired extension in this case. If IA&LE(%'), then2'(%'u{A})={f+rIA;f ~2'(%'), r rational}. On2'(%'u we define a functional T as follows. For f +rIA in 2'(%u{A}), T(f + T I A ) = T(f)+rd , where d is a fixed real number. We claim that is a well defined functional on 2(%' u {A}).Let f l + rlIA = f 2 + r2IA for some ') rl, rz rationals. This implies that f l -f 2 = (r2-r1)IA. Since fl, fz in 9(%and f1, f 2 ~ 2 ' ( % ' f1-f2E2'(%'). ), Since IA@2'(%'),it follows that rZ-r1= 0. Consequently, f I =f2. From this, it follows that is well defined on 2'(%' u {A}). It is indeed a linear functional on 2'(%u {A}). Consequently, the set function fi on %' u {A} defined by

{h}),

fi (B) = T(IB) for B in %' u {A} is a real partial charge on %u{A}. See Theorem 3.1.7(3).This completes 0 the proof. The following is the desired extension theorem. 3.2.5 Theorem. Let p be a real partial charge on a collection %' of subsets of a set R. Let 9be any field on R containing %'. Then there exists a real charge on 9which is an extension of p from %' to 9.

Proof. We give a proof based on Theorem 3.2.4 and transfinite induction. Let a. be the least ordinal corresponding to the cardinal number of the collection 9- V. Write 9- %' = {A, ;a ordinal, a < ao}. For each ordinal a
uBc,

u,<,,

Now, we come to the problem of extending positive real partial charges defined on a given collection %' of subsets of a set R to any field 9 on R containing %' as a positive real partial charge. This may not be possible always. Successful extension depends, to some extent, on whether R E %' or not. If R E %', we show that an extension is always possible. If fi & %', the given positive real partial charge on %' can be extended to 9as a positive partial charge but this extension might take the value co on some sets. First, we consider the case R E %'.

66

THEORY OF CHARGES

3.2.6 Definitions. Let V be any collection of subsets of a set R with R E V. Let p be a positive real partial charge on V.For any subset A of R, let

where the supremum is taken over all finite sequences A>,Az, . . . ,A, and B1, Bz, . . . , B, from %' satisfying the condition that m

kIA+

n

Iq z i=1

C

lai

j=l

for some positive integer k . Also, for any subset A of s1,let

where the infimum is taken over all finite sequences Al, Az, . . . , A, and B1, Bz, . . . ,B, from %' satisfying the condition that n

m

I B i + kIA C IA, 2 i=1 i=1

for some positive integer k . The supremum defined above always makes sense. One can take any set C in %' and note that IA+IC?Ic. The infimum defined above is also meaningful since fz E %'. The following proposition puts p i and pe into proper perspective in relation to the extension problem. 3.2.7 Proposition. Let %' be a collection of subsets of a set R with R E V. Let p be a positive real partial charge on V.Let A be any subset of R. If @ is a positive real partial charge on %' u{A} which is an extension of p, then

pi(A) 5 F (A)5 pe(A).

Proof. We prove the inequality pi(A)5 @(A). Let AI, At, . . . ,A,, B1, Bz, . . . , B, be sets from %' satisfying the condition that kIA++C,Tl I B i 2 I,"=, I*, for some positive integer k . Since @ is a positive real partial charge on %u{A}, we have k @ ( A ) + C ~ = l F ( B i ) r C ~ = , F ( A Since i ) . t;i is an extension of p from V to V v{A}, we have

Consequently, we obtain the inequality @ (A) 2 pi(A) by taking supremum

3.

EXTENSIONS OF CHARGES

67

over all finite sequences with the property specified above. The proof of the other inequality is similar. 0 From the above proposition, it is clear that when seeking an extension p from % to % u {A}, the choice of the number fi (A) should confirm to the inequalities established above. The following proposition gives some properties of the set functions pi and pe.

II. of

3.2.8 Proposition. Let % be a collection of subsets of a set R containing R. Let p be a positive real partial charge on %. Let pi and pe be the set functions on the power set B(Q)of R as defined in Definition 3.2.6. Then the following statements are true. (i). 0 5 pi(A) Ipe(A)5 p (0)for every A c R. (ii). If A E % or I A E 9(%), then pi(A) = pe(A)= T(IA),where T i s the linear functional on 9(%) induced by p. (iii). If A, B c R and A n B = 0, then pi(A)+pi(B)Ipi(AuB)Ipi(A)+pe(B) spe.(AuB)Ipe(A)+~~e(B). (iv). If A E %, B c R and A n B = 0, then

and (v). I f A , B c R , A n B = 0 a n d A u B E % , t h e n P (A u

B) = Fi(A) + pe(B) = pe(A) + pi@).

In particular, for any A contained in R, pi(A)+ pL,(AC) = pi(A‘) + pe(A)= CL

(W.

Proof. (i). For any B in %, IA +IB2 IB.Consequently,

Since R is in % and In + In 2 In + IA, we have

LetAl,AZ,.. . ,A,;B1,B2,. . . ,B,;C1,CZ,. . .,C,;andD1,D2,. . . ,D, be sets from % such that kIA + I , : I B j 2 IAj for some positive integer k , and Icj ID,+SIA for some positive integer s. From these inequalities, it follows that

xi”=,

c,!=,

68

THEORY OF CHARGES

so, P

k

C

Iq+S

j=l

m

n

4

j=l

j=l

j=l

C IB,?sC IAi+k C ID^.

Since p is a positive real partial charge on %', we obtain

Rearranging these terms, we get m

C;=I p (Cj)-Xi"= 1 P (Dj), Cjn=1 CL (Aj)- Cj=1 P (Bj) k

S

Hence pe(A)? pi(A). (ii). If I A E ~ ( % ) we , can write rA= riIci for some C1, Cz, . . . ,C, in % and r l , r2, . . . ,rm rationals. Writing ri = n i / N for i = 1,2, . . . , m, where n l , nz, . . . ,n , are integers and N is a positive integer, we can rewrite the above as

EL,

with p 2 1, q 2 1 and A1,AZ,.. . ,Ap, B1, BZ,.. . , B, {Cl, Cz, . . . , C m } .The above representation gives

coming from

Hence pi(A) = pe(A)= T(IA). (iii). Let Al,Az,. . . , A n ; B1,B2,.. . , B m ; C1, C Z ,.. . , Cp and D1, DZ, . . , , D, be sets from %' such that kIA+CLl I,, IA,for some positive integer k, and s I ~ + C ; =ID, ~ ?C:=, Ic, for some positive integer s. Then

Consequently, by observing that I A v B

=I A

+I B , we get

3.

69

EXTENSIONS OF CHARGES

The above inequality can be rewritten as

From this, it follows that pi(Au B)rpi(A)+pi(B). Now, we show that pi(Au B) Ipi(A)+p,(B). Let A1, Az, . . . ,A n ; B1, Bz, . . . , Bm;C1, Cz, . . . , Cp and D1, Dz, . . . , D, be sets in % such that k(IAUB)+C,ElI B i ZC,!=, IAi for some positive integer k, and ID, z Ici+ S I B for some positive integer s. Since I A u B = IA+ I,,

xi"=,

Multiplying throughout by ks, we obtain 4

m

k C I D ~ + SC j=l

j=l

IB,+kSIAzS

n

P

j=l

j=l

1 IAj+k C

Ici.

Consequently,

Taking supremum over A1, AZ,. . . , A,; B1, Bz, . . . , B,; k, first and then supremum over C1, Cz, . . . ,C,; D1, Dz,. . . ,D,; s, we obtain p i ( A ) z pi(Au B) - pe(B). From this, the desired inequality follows. The rest of the inequalities can be proved analogously. (iv). This follows from (ii) and (iii). (v). This follows from (iii). The second part follows if we observe that RE V. O The following theorem paves the way for the extension of positive real partial charges.

3.2.9 Theorem. Let V be any collection of subsets of a set R with R E%. Let p be a positive real partial charge on %. Let A c R be such that A & V. Then there exists a positive real partial charge on V u {A} which is an extension of p. Proof. Let T be the linear functional on Z ( V ) induced by p. Case (i). I A E Z ( % ) . Then the set function fi on Vu{A} defined by F(B) = T(IB), B in V u{A}, is a partial charge on % u{A} and it is the desired extension of p from V to V u {A}. From Proposition 3.2.8(i) and (ii), it follows that F is positive. Case (ii). I ~ & i ( g )Observe . that Z(%'u{A})= {f+rIA;f E 9(%) and r rational}. Choose and fix a real number d satisfying pi(A)~d 5 pe(A). Obviously, by Proposition 3.2.8(i), d 2 0. Define on i(% u{A}) by T ( f + r I A )= T ( f )+rd for f in A?(%) and r rational. We

70

THEORY OF CHARGES

is well defined. Suppose f l +rlIA = f2+r2IA for some f l , f i e -f 2 = (r2- rl)IA.Since la& 9 ( V ) and 2 ( V ) is a linear space, we must have r2 = rl. Consequently, f l =f 2 . Hence T is well defined on 2(% u {A}). Define fi on V u {A} by EL ( B )= F(IB)for B in % u {A}. fi is obviously an extension of p from % to V u {A}. fi (A)= d 2 0. This implies that 6 is positive. Since is well defined, fi is a partial charge. From the inequality pi(A)5 d Ipe(A), it follows that ii is a positive real partial charge on V u {A}. 0 show that

2(%) and r l , r2 rationals. Consequently, f

3.2.10 Theorem. Let V be any collection of subsets of a set R with R E %. Let p be a positive real partial charge on %. Let 9 b e any field on R containing V.Then there is a positive charge p on 9 which is an extension of p.

Proof. One can give a proof based on transfinite induction and Theorem 3.2.9. The argument is similar to the one presented in Theorem 3.2.5. 0

3.3 EXTENSION PROCEDURE OF LOS AND MARCZEWSKI The extension procedure described in the previous section consists of extending the given set function on a given collection of sets to the collection of sets obtained by adjoining just a single set to the given collection of sets. In this section, we present a procedure due to Los and Marczewski for the extension problem which can be described as follows. Let 9 be a and V a subfield of 9. Let p be a positive field of subsets of a set bounded charge on V.Let A E 9 be such that A &V. Let 9 ( V , A) denote the smallest field on R containing V and A. The procedure due to Los and Marczewski consists of extending p from V to 9 ( V , A) as a positive charge in one step. Repeating this procedure, one can extend p from V to 9 as a positive charge. First, we observe that the expressions for pi and pe introduced in Section 3.2 simplify if the domain of p is a field of sets, as the following proposition demonstrates.

3.3.1 Proposition. Let V be a field of subsets of a set R. Let p be a positive bounded charge on V. Let pi and pe be the set functions on the power set P ( R ) of R as defined in Definition 3.2.6. Then for any subset A of s1, (i). pi(A) = Sup { p ( B ) ;B c A, B E %} and (ii). pe(A)= Inf {p (C); A c C, CE V}.

Proof. We prove (i). The proof of (ii) is similar. Let A1, A2,. . . ,A,, B1, B2, . . . , B m be sets from V such that m

kLlIA+

n

1 I B i 2?i 1 IAi i=l =l

3.

71

EXTENSIONS OF CHARGES

for some positive integer ko. We show that there is a set F1 in V such that F1c A and

Since 0 E Ce, we can assume that m = n. Define for each 15 k

6Ai,

u

c k =

I n,

s n j =1

15it
and

By Lemma 3.1.4, n

n

n

i=l

k=l

n

1 I*;= k1 Ick i=l =l

C I B ~ =1 ID,.

and

Then

This leads to n

n

koIA+

n

n

i=l

i=l

c ID;-c~ + c I D ~ ~ c1, Ic;-D; +1 2

i=l

i=l

ICinDi.

This can be written in the form n

k0IA-k

c

n

2

i=l

1 Ic;-D~. i=l

-

-

Since C1 3 C2 3 ' 2 Cn and Dl 3 D23 * * 3 D,, (Di-Ci) n (Cj -Dj) for all i, j = 1,2, . . . ,n. Now, the inequality reduces to n

kora?

=0

n

IC;-Q =

i=l

c I,,

i=l

Say.

Let, for each 15 k I n , F k =

U lsiI
k

n Eii.

j=1

zy=l

--

= Note that F1 3 F22 .IF, and by Lemma 3.1.4, Let k l be the largest integer such that Fk,# 0. (If F1= 0 ,clearly F1= A and ~ ; = 1p(Ai)-C:=l

ko

p(Bi)

5 0 = p (Fi).)

72

THEORY OF CHARGES

IFi and F12 F23 * Since k J A 2 F1. Consequently,

-

*

2 F,,

it follows that A'c F; or A 3

Hence pi(A)5 Sup { p (B); B c A, B E %'}. On the other hand, for any B in %' and B c A, observe that 1, + 1, r> IB.So, gi(A) 2 [ p (B) - p (0)]/1= p (B). Therefore, pi(A) 2 SUP{ p (B); B c A, B E %'}. This proves the desired equality.

0

If %' is a field of sets, pi and pe exhibit some additional properties as the following proposition indicates.

3.3.2 Proposition. Let %' be a field of subsets of a set R and p a positive bounded charge on %. Let pi and pe be the set functions defined on P(R) as in Definition 3.2.6. If A and B are two subsets of R satisfying the conditions that A c C, B c D, C nD = 0 and C, D E %',then pi(A u B) = pi(A) + pi(B)

and pe(AuB)=pe(A)+pe(B).

Proof. We prove the first assertion. The proof of the second is similar. By Proposition 3.2.8(iii), pi(A)+pi(B)Ipi(Au B). By Proposition 3.3.1, for any given E >0, we can find E c A u B such that E E %' and p(E)2

3.

EXTENSIONS OF CHARGES

73

pi(Au B) - E . Note that pi(A uB)-E S p ( E )= p(E n(C u D ) ) = p((En C ) u (E n D ) )

+

= @ ( E nC) p(E nD) 5 pi(A) +pi@)

as E n C c A and E n D c B . Since E > O is arbitrary, it follows that 5 pi(A u B) 5 pi(A)+ pi(B). Hence pi(A u B) = pi(A) + pi(B). Now, we prove the extension theorem.

3.3.3 Theorem. Let % be a field of subsets of a set a.Let p be a positive bounded charge on %. Let A c n be such that A&%.' Let 9(%, A) be the smallest field on R containing % and A. Then there exists a positive bounded charge fi on 9 ( V , A) which is a n extension of p . Moreover, if d is any real number between pi(A) and pe(A), then there is a positive charge fi on 9(%, A) such that fi (A) = d and fi is an extension of p from % to 9(%, A). Proof. Choose and fix a number d E [pi(A),pe(A)]. Then, for C in 9(%, A), let cL(C) = a [ p i ( C ~ A ) + p e ( C ~ A ' ) l + ( l - a ) [ p e ( C n A ) + p i ( C ~ A c ) l , where a satisfies the equation d = api(A)+ (1- a)pe(A). Obviously, O s a 4 1. fi is a positive real function on 9(%, A). We show that fi is an extension of p. Let CEV. Since ( C n A ) u ( C n A ' ) = C E % and ( C n A ) n (CnA')= 0, by Proposition 3.2.8(v), p i ( C n A ) + p e ( C n A c = ) p(C)= pi(Cn A') + pe(CnA). Consequently,

fi (C) = ap (C) + (1- a l p (C) = p (C). This proves that cL is an extension of p from % to 9(%, A). It remains to A). Let p l , p2 be the set functions be shown that fi is a charge on 9(%, A) by defined on 9(%, p 1 (C) = pi(CnA)

+ pe(CnA'),

C in 9( V,A)

and

pz(C>= pi(CnA')

+ pe(Cn A), C in 9(%, A).

It suffices to show that p1 and p2 are charges on $(%, A). Now, we look at p1. Let C, D E 9(%, A) be such that C n D = 0. Then we can write C = ( C l n A ) u ( C ~ n A ' )a n d D = ( D 1 n A ) u ( D 2 n A Cfor ) some C1,C2,D1, D2 in %. See Proposition 1.1.13. By replacing C1 by CI -D1, D1 by DI -CI, C2by C2- D2 and D2by D2- C2, if necessary, we can assume that C1n D =

74

THEORY OF CHARGES

0 and CZnDZ= 0. This is possible since C nD = 0. We note that p

(C u D) = p i( (C u D) nA) + pe((C u D) nA')

+

= p i( (C nA) u (D nA)) p e( (C nA')

u (D nA'))

= pi((C1nA) u (Di nA))+ pe((Cz nA') u(Dz nA')) = Fi(C1nA) fpi(D1 n A) +pe(CznA') +pL,(Dzn A')

(See Proposition 3.3.2.) = pi(C1 nA) + p e ( G nA')

+ Fi(D1 nA) + FePZ nA")

+ pe(C nA') + pi(D nA) + pe(DnA') = Pl(C) + p 1D).

= pi(C nA)

This shows that p1 is a charge. By a similar argument, one can show that pz is a charge. Consequently, @ = a p l + (1- a ) p z is a charge. The above theorem leads to the general extension result. 3.3.4 Corollary. Let U be a field of subsets of a set 0 and p a positive bounded charge on U.Let 2F be a field on 0 containing %. Then there exists a positive bounded charge @ OIE such that @ is an extension of p from % to 9and that the range of fi is a subset of the closure of the range of p on U.

Proof. Let &)

be the closure of the range of p on U.Let

X={(B, v, 9, A ) ; U C Bc 9 c 9 , B and 9are fields on 0, v is a positive charge on B, A is a positive charge on 9,A/W = v, v/U = p and the range of A is contained in &)}. ( v / U is the charge v restricted to the subfield U.)On X, we introduce a partial order Ias follows. For (Bl,vl, g1,A l ) and (Bz,VZ, 9 2 ,Az) in X, say (281,v1, 91, A l ) 5 ( B z , v2, gZ, A2) if the following are satisfied. (i) B z c B l . (ii) v 1 / B z = vz. (iii) 9 1 c gZ. (iv) A z / 9 1 = A 1 . Let {(Bm, v,, gm, A m ) ; a E I'} be a chain in X. Let 93 =nuer Be, 9= Uacr9,, v the restriction of va0 from Boo to B for any a. fixed and A on 9be defined by A (D) = A,(D) if D E 9,, a E r. A is well defined on 9 and is a positive charge on 9. The range of A is contained in &). It follows v , ~ , A ) E Xand is indeed an upperbound of the chain that (3, {(B,, v,, 9,, A,); a E r}.By Zorn's lemma, there is a maximal element

3.

75

EXTENSIONS OF CHARGES

(930, vo, 90, Ao) in X. It obviously follows that a0= %' and v o = p. We claim that go= 9. Suppose gois properly contained in 9. Let A E 9-90 and %'*= 9(90, A). Let Aoi and hoe be as defined in Definition 3.2.6 for the charge A 0 on 90.Define A * on V* by

+

A *(C)= A oi( C nA) Aoe(CnA')

for C in %*. We have already seen in Theorem 3.3.3 that A * is a positive charge on %'*and is indeed an extension of A. from goto %*. We now show that the range of A * is contained in R ( p ) .Let B,, n z 1be a sequence in gosuch that B, c C nA for every n L 1 and Ao(B,) = Aoi(CnA). Let D,, n L 1 be a sequence in 90such that C nA' c D, for every n 2 1 and lim,,,Ao(D,)=Aoe(CnAc). Then CnA'cD,-B, for every n 21. Consequently, Ao(D, -B,) = Aoe(CnA') since Aoe(CnA') 5 Ao(D, -Bn) sAo(D,) for every n L 1. Therefore, lim Ao(Bnu D,) = lim Ao(B,) + lim Ao(D, -Bn)

n-rm

n-02

= Aoi(C nA)

n-tm

+ Aoe(CnA')

= A "(C).

Hence, the range of A * is a subset of the closure of the range of Ao. But the range of A. is contained in &). It now follows that @lo,V O , %*, A *) E X and (930, V O , 90,Ao) (30, vo, %*, A *). This is acontradiction to the maximality of (90, V O , 90, Ao). Hence go= 9, A. is the desired extension of fi from % to 9. This completes 0 the proof. This result can also be proved using Transfinite induction. As a special case of the above theorem, we can prove that every filter in a field 9 on R is contained in a maximal filter in 9.

3.3.5 Corollary. Let p be a 0-1 valued charge on a field % of subsets of a set R. Let 9 be any field on R containing V. Then there is a 0-1 valued charge fi on 9 which is an extension of p from V to 9.Equivalently, every filter in 9is contained in a maximal filter in g. Corollary 3.3.4 can also be used to extend bounded charges from % to 9.

3.3.6 Corollary. Let %' be a field of subsets of a set R and p a bounded charge on V. Let 9 be any field on R containing %'.Then there exists a bounded charge fi on 9 which is an extension of p. Proof. Apply Jordan Decomposition theorem to on %' and then apply Corollary 3.3.4 for positive and negative variations of p separately. See Theorem 2.2.2(1). 0

76

THEORY OF CHARGES

3.4 EXTENSION OF PARTIAL CHARGES IN THE GENERAL CASE In Section 3.2, we dealt with the extension of positive real partial charges defined on a given collection %' of subsets of a set R when R E U. In this section, we examine the situation when R & % and also the extension of partial charges on U taking infinite values.

3.4.1 Lemma. Let % be a ring of subsets of a set R, where R &%'. Let p be a positive real charge on U. Let 9 be the field on R generated by %.' Then there exists a positive charge fi on 9possibly taking the value infinity which is an extension of p from u to 5

Proof. Let % I = { A ~ R ; A '%}. E By Theorem 1.1.9(4), 9=% u U 1 . Let d = Sup { p ( C ) ;C E U}. Case (2). d = 00. In this case, define fi on 9 as follows.

fi (A) = p (A), if A E U, ifAEU1.

=a,

We claim that fi is a positive charge on 9. (It is obvious that fi is an extension of p from U to 9.)Let A, B E 9 and A n B = 0. Case (i). A, B E U. Obviously, fi ( A u B) = lu. ( A u B) = p (A)+ p (B) = fi (A) + fi (B). We claim that A u B E Y1. For, (AuB)'= Case (ii). A E U and B E A'n B' = B'-A E % as B'E %, A E % and %' is a ring. Consequently, fi (A u B) = co = p (A) + 00 = p (A) + fi (B) = fi (A) + fi (B). Case (iii). A E g1 Then and B E U, This is analogous to Case (ii). Case (iv). A, R = A" u B' E % which is not possible since & U. So, case (iv) does not arise. Hence fi is a charge on 9. Case (2).d < co. In this case, we define fi on 9as follows. if A E U ,

fi (A) = Er. (A), =d-p(A'),

ifAEU1.

We claim that fi is a positive bounded charge on 9.The positivity of El. is obvious. Let A, B E 9 and A n B = 0. Case (i). A, B E U. Then fi (A u B) = p ( A u B ) = p ( A ) + p ( B ) = ~ ( A ) + @ ( BCase ) . (ii). A E U and BE%'^. As proved above, A u B E U l . Therefore,

fi (A u B) = d - p ((Au B)') = d - p (B'= fi (B)

= d - p (A"nB')

A) = d - p (B")+ p (A)

+ p (A) = fi (A) + fi (B).

Case (iii). A E U1 and B E %'.This case is similar to Case (ii). Case (iv).

3.

EXTENSIONS OF CHARGES

77

A, B E As in Case (iv) under Case (1)above, this is not possible. Hence fi is a charge on 9 under Case (2) too. 0 Now, we come to the result which complements Theorem 3.2.10.

3.4.2 Theorem. Let % be a collection of subsets of a set R with R @%. Let 9be any field on R containing %. Then there exists a positive charge F on 9 (possibly taking the value co) which is an extension of p from % to 9,

p be a positive real partial charge on %. Let

u;=,

Proof. Let 9 = {AE9;A c Ci for some C1, C2,. . . ,C, in %}. It is clear that 9 is a ring on R. First, we show that + can be extended from % to 9 as a positive real partial charge on 9. Observe that pi(B) is well defined and is a real number for any B c R. pe(A)is also well defined and is a real number for any A in 9. See Definition 3.2.6 and the remarks following this definition. Using the argument given in the proofs of Theorems 3.2.9 and 3.2.10, we can find a positive real partial charge E. on 9 which is an extension of p on %. Note that every partial charge on a ring is a charge. Now, we extend E. from 9 to 9as a positive charge. This can be done as follows. Let d = Sup {$ (D); D E 9}. Case (i). d = CO. Define p on 9 as follows. p(A) = $(A), if A E9, = CO,

if A E9-9.

As in the proof of the previous lemma, one can show that is a positive charge on 9which is obviously an extension of p from % to 9. Case (ii). d
if A E ~ ,

- fi (A'), if A E

-9.

Using the argument given in the proof of Lemma 3.4.1, one can show that is a positive bounded charge on 9 1 which is obviously an extension of p from %. By Corollary 3.3.4, there exists a positive bounded charge F on 9which is an extension of p from %. This completes the proof. 0 Now, we give a condition under which a positive real partial charge on a collection % of subsets of a set R admits an extension E. on 9 which is a positive bounded charge, where 9 is any given field on R containing %. 3.4.3 Theorem. Let p be a positive real partial charge on a collection % R. Let 9 be a field on R containing %. Let 9 = {A E 9; A c Uya1Cifor some C1, Cz, . . , ,C, in %}. Let + e be the set function

of subsets of a set

78

THEORY OF CHARGES

defined on 9 as in Definition 3.2.6. Then there exists a positive bounded charge fi on 9which is an extension of p from % if Sup {pe(D);D E 9} < a.

Proof. The proof of this result is essentially contained in the proofs of 0 Theorems 3.4.2 and 3.2.9. Finally, in this section, we take up the case of charges taking infinite values.

3.4.4 Theorem. Let % be a field of subsets of a set SZ and 9be any field on R containing %. Let p be a positive charge on %possibly taking the value 00. Then there exists a positive charge fi on 9 which is an extension of p from % to g.

Proof. Let 9 ={A E %; p (A)< 00). 9 is obviously a ring on R. Let A be the restriction of p to 9. A is a partial charge on 9. Then by Theorem 3.4.2, we can find a positive charge h on 9 which is an extension of A from 9 to 9.Define fi on 9 as follows. Let A E9.

6

1-7. (A)= h(A), if A c A i for some finite number of sets i=l Al, AZ,. . . , A,, from 9, = a,

otherwise.

fi is the desired extension of is a charge on 9.

p

from % to 9.One can easily check that fi

0

Next, we deal with general charges.

3.4.5 Theorem. Let % be a field of subsets of a set R and 9 a n y field on R containing %. Let p be a charge on % not necessarily real valued. Then there exists a charge fi on 9 which is an extension of p from % to g.I f p is real valued, one can choose fi to be real valued.

Proof. One can give a proof along the lines of the ideas given in the proof 0 of Theorem 3.4.4, using Theorem 3.2.5.

3.5 MISCELLANEOUS EXTENSIONS

In this section, we give various classical extension theorems in some special cases, some of them without proofs.

3.

EXTENSIONS OF CHARGES

79

3.5.1 Theorem. (i). Let % be a semi-ring of subsets of a set 0. Let p be a real charge on V.Let 9 be the smallest ring on R containing %. Then there exists a unique real charge p on 9 which is an extension of p from % to 9. If p is positive on %, so is fi on 9. (ii). Let V be a semi-field of subsets of a set R. Let p be a real charge on V.Let 9be the smallest field on R containing %. Then there exists a unique If p is positive real charge rii on 9which is an extension of p from % to 9. on V,so is 6 on S. (iii). Let % be a lattice of subsets of a set R with 0E % and p a strongly additive real function on V.Let 9be the smallest semi-ring on R containing %. Then there exists a unique real charge p on 9 which is an extension of p from %to 9.If p is positive on %and satisfies the condition that p (A)5 p (B) whenever A, B E V and A c B, then lj; is positive on 9. (iv). Let V be a ring of subsets of a set R and p a real charge on %. Let 9 be the smallest field on R containing %. Then there exists a unique real charge p on 9 such that fi(fl) is a prescribed number. If p is a positive charge on %, there is a positive charge fi on 9 which is an extension of p. Such a p is unique if p (R) = Sup { p (B); B E %} and p is positive real valued. (v). Let p be a positive bounded charge on an additive-class % of subsets of a set R. Let 9 be the smallest field on R containing %. There need not exist a positive bounded charge on 9 which is an extension of p. Proof. Even though the results of this theorem can be proved using some of the results of the previous sections, we give direct proofs. (i). By Theorem 1.1.9(2), 9 = { A c R ; A is a finite disjoint union of sets Ci for some from V}.Define p on 9 as follows. Let A E 9.Then A = pairwise disjoint sets in V. Set p(A)=CE, p(Ci). We show that fi is unambiguously defined. Suppose A = Ci = D , where C1,Cz , . . . ,Cm are pairwise disjoint sets in % and D1,D 2 , .. . ,Dn are pairwise disjoint sets in %. Then

uy=l u?=l uyZl

u u (CinDj). m

A=

n

i=1 j=1

u;=l

Note that Ci = (Ci nDj) for every 1 5i 5 m and Ci nDj E V for all i and j . Similarly, Dj = uE1(Ci nDi) for every 15 j 5 n. Since p is a charge on %, we have m

and

m

n

80

THEORY OF CHARGES

This proves the unambiguity of the definition of fi. It is obvious that fi is a real charge on 9 and is an extension of p from V to 9.The uniqueness of fi is also clear. If p is positive on V,so is fi on 9.This completes the proof of (i). (ii). This is similar to (i). }. on9by (iii). ByTheorem 1.1.9(1),~ = { F - E ; E , F E V , E ~ F Definefi ii(F- E) = p (F)- p (E) for E, F E V and E c F. We prove the unambiguity of the definition of fi on 9.Suppose F1-El = Ft - E2 for some El, F1, El, FZ in V with E l c F 1 and E2cF2. So, F z u E 1 = F l u E 2and F z n E l = FlnE2. Since p is a modular function on %, p(F2)+p(E1)= E.L (F2 u El) + p (FznEd = CL (F1u E d + p (FI n E d = p (Fd + p 032). Hence p (Fz)- p (E2)= p (FJ - p (El).This shows that fi is unambiguously defined on 9. We now show that fi is a charge on 9. Note that f i ( 0 ) = 0 . Let F1-El and F2- E2 be two disjoint sets in 9such that (F1-El) u (F2 - Ez)= F3- E3E 9, where El, F1, EZ,F2, E3, F3E V,El c F1, Ez c Fz and E3c F3. In order to show that fi (F1- El) + fi (F2- E2)= fi (F3- E3), it suffices to show that p (FI)+ p 0%)+ p (Ed = p (F3)+ p (El)+ p W. Clearly,

F1 u F ~ E3 u = F ~ El u u Ez, (F1nF2) u (F1nEd u (Fz E3) = (El nEz)u (El F3) u (Et nF3), and

F1n F z n E3= F3nEl nEz. By Proposition 3.1.5, the desired equality follows. Since p (0)= 0, it follows that fi is an extension of p. It is obvious that fi is unique. If p is positive and monotone on V,then fi is positive on 9. (iv). Assume that R &%'.(If R E V,then 9= V.)Let Vl ={A; A'E %}. By Theorem 1.1.9(4),9=V u Vl. Let d be any prescribed number. Define fi on 9 as follows.

fi (A) = I*. (A),

if A€%':,

= d - p (A"), if A E

%I.

As in the proof of Lemma 3.4.1, one can show that fi is a charge on 9. fi is, obviously, an extension of p from V to 9.Uniqueness of fi with the property that fi (a)= d also follows easily. If p is a positive charge on %, define fi on 9by fi(A)=p(A), ifAE%,

=a,

ifAEV1.

fi is a positive charge on 9 and is an extension of

p

from V to 9.

3.

81

EXTENSIONS OF CHARGES

If p is a real positive charge on %, define r*. on 9 by if A E %,

fi (A) = p (A), =d-p(A'),

ifAEV1,

where d = Sup { p (B); B E %}. fi is the desired extension of (v). Here is an example. Let a= (1,2,3,4} and = ( 0 ,{1,21, K 3 1 , {1,41,(2,317 (2,417 (3,417

p.

a).

% is an additive-class on R. The smallest field 9on R containing % is the power set 9(a)of R. Let p on % be defined by p ( 0 ) = 0 , p{1,2})=$= p1.(3,4)),p({l,3))=1, pCL{2,41)=0, p(U,4>>=a,p({2,3))=.% p ( W = l . /Jis a positive bounded charge on %. But there is no positive bounded charge on 9 which is an extension of p. 0

Another important extension theorem is the following theorem of Caratheodory.

3.5.2 Theorem. Let p be a positive bounded measure on a field 9 of subsets of a set R. Let be the smallest a-field on R containing 9. Then there exists a unique positive measure on which is an extension of p. Proof. In any standard text book on Measure theory.

0

Related to the above theorem is the following approximation theorem.

3.5.3 Theorem. Let p be a positive bounded measure on a u-field of subsets of a set R. Let %be any field on R generating Then for any A in and E > 0, there exists F in F s u c h that p (F A A) < E.

a.

Proof. Let 9={A€ '? for I;every E > O there exists F in 9 such that p (A A F) ;< E}. Clearly, 9c 9 and 9 is closed under complementation. We shall show that 9 is closed under countable unions which will complete the proof. Let A,,, n 2 1 be a sequence in 9and E > 0. For each n L 1, let F, €9be such that p(An A F , ) < E / ~ " + ~Let . m 2 1 be such that p(UnzlF, -U:=i Fi) < ~ / 2NOW, .

+pi(

u Fn) A (6Fn))

nrl

n=l

82

THEORY OF CHARGES

We need some results about measures on topological spaces which we shall state here.

3.5.4 Definition. Let X be a compact Hausdorff space and 9 its Borel u-field. A positive bounded measure p on 9 is said to be regular if p (A) = Sup {p ( C ) ;C compact,

C c A}

for every A in 9.

3.5.5 Theorem. Let X be a compact Hausdorff space, 90its Baire a-field and 93 its Borel a-field. Then any positive bounded measure on 30can be extended uniquely as a regular measure on 9. Proof. See Theorem D on p. 239 of Halmos' Measure theory.

0

3.6 COMMON EXTENSIONS The problem considered in this section is the following one. Let 9 be a field of subsets of a set R and V and 9 be two subfields of S. Let p1 and p 2 be two positive charges on % and 9 respectively. Under what conditions can we find a positive charge p on 9 which is an extension of both p 1 and p2 to 9?The condition needed, surprisingly, turns out to be a natural one.

3.6.1 Theorem. Let % and 9 be two fields on a set R and p1 and p2 positive bounded charges on % and 9respectively. Let 9 be a field on R containing both V and 9. Then a necessary and sufficient condition for the existence of a positive bounded charge on 9which is a common extension of both p 1 and p2 is that pt(C)2 ~ . z ( D )whenever C E %, D E 9and C 2 D,

and p l ( E ) s p ~ ( F )whenever E E %, F ~ 9 a n dE c F .

Proof. The necessity of the condition is obvious. We will prove the sufficiency. From the given condition, it follows that p l(A)= p2(A) whenever A E % n9. We define a function El. on % u 9 unambiguously as follows. El. (A) = p (A), if A E %', = p2(A), if A E9.

We now show that El. is a positive real partial charge on % u9. Let At,A2,. . . , A,,, and Bt, B2, . . . ,B,,, be two finite sequences of sets from

3.

83

EXTENSIONS OF CHARGES

% v 9 such that P+q

m+n

C

C

IAi

i=l

IBi-

i=l

Assume, without loss of generality, that A l , A z , . . . , A m € % , . A m + , E 9,BI, Bz, .,Bp E %' and Bp+l, B ~ + z *,.. ,Bp+q E 9. A m + l Am+2,. , The above inequality can be written in the form m n " a C IA,+ C IA,,,2 IB,+ IB,,,.

-

9

i=l

2

i=l

2

i=l

i=l

Since 0 E % n9, we can assume, without loss of generality, that m = p and n =q. By Lemma 3.1.4, we can assume A 1 1 A z 3 . - 3 A m ;A m + l ~ A m + 2 3 . 1 A m + " ; B 13 , B ~ l* - 3 B p ; B p + l3 B p + Z3 3BP+,.Theabove inequality can be rewritten in the form

-

m

-

m

n

IAz-B, i=l

+

n

IA,+i-B,+i

IBi-Ai

i=l

+C

IB,+i-A,+,*

i=l

i=l

Let Ci=Ai-Bi, i = l , 2 , . . . , m ; Di=Bi-Ai, i = l , 2 ,..., m ; E i = Amci-Bmti, i = 1 , 2 , . . . ,n ; Fi = Bmti-Am+i, i = 1 , 2 , . . . ,n. The above inequality then becomes m

m

n

C I C , +i = l IEi i=l

n

C

ID,

+C

IFi.

i=l

i=l

Observe that Ci nDj = 0 for all i and j and Ei nFj = 0 for all i and j . By Lemma 3.1.4, we can assume that C13 C z 3 -. 3 C m ;D13 D z 3 . 3 D m ; E I =JEZ3 * * 3 E n; FI 3 FZ * 3 Fn. The above inequality leads to two inequalities:

-

-

m

n

m

n

C I c i ri C= l IF, and i-1

C I E , 2 i = l ID,. i=l

Note that C1, Cz, . . . , C,, D1, Dz, . . . , D, E %' and El, Ez, . . . , En, F1, FZ,. . . , Fn E 9. Now, observe that Fi c Ci and Di c E i for all i. Consequently, by the given condition, m

n

i=l

m

n

C p l ( C i ) r C pZ(Fi) and C i=l

pZ(Ei)>

i=l

C p1(Di).

i=l

Hence

f

i=l

fi(Ci)+

fi(Di)+

fi(Ei)z

i=l

i=l

f. fi(Fi).

i=l

From this, it follows that (using Proposition 3.1.5), m+n

P+cq

C fi(Ai)? C fi(Bi)*

i=l

i=l

84

THEORY OF CHARGES

Hence fi is a positive real partial charge on % u9.By Theorem 3.2.10, we can find a positive bounded charge p on 9 which is an extension of 6 from % u $3to 9. This completes the proof. Now, we take up the case of real charges.

3.6.2 Theorem. Let % and 9be two fields on a set R and p l and p2 two real charges on % and 9respectively. Let 9 be a field on R containing both V and 9. A necessary and sufficient condition for the existence of a real charge p on 9 which is a common extension of both p 1 and p z is that p1(A) = pz(A)for every A in % n9. Proof. The proof of this theorem is similar to the one given for the previous theorem, It may be remarked that these two theorems remain valid if p l and take infinite values.

pz

The two theorems proved above are not extendable to the case when Here are the relevant examples. there are more than two subfields of 9.

3.6.3 Example. Let R={l,2,3,4}; %1=

9=P(R);

(0, {1,21,{3,41, R1; V2 = (0, K 3 1 , (2341, n1; %3 = (0, (1,419 (2,313 n1;

pi({1,2))=& p2({2,41) =

t;

pi({3,4})=% p3({1,41) =

a,

@2({1,3))=$, p3({2,31) = .:

Each pair of p1 and p 2 , p l and p3, kz and p 3 satisfies the condition of Theorem 3.6.1. But there is n o positive charge on 9 which is a common extension of all the three charges p l , p2 and p 3 .

3.6.4 Example. Let

R = {1,2,3}; %1=

9=P(R);

(0, (11, (2,319 R1; %2 = i0, (21, {1,31, R1; V3 = (0, (31, (1,219 a);

@11({1I)=i=E.L1({2,31); p2({21)=&p2({1, 31)=f; 113({31)=

a,

p3({1,21) =

t.

Note that p l= p 2 on V l n V 2 , p l= p 3 on V 1 n V 3 and p 2 = p 3 on V2nV3. But there is no real charge p on 9 which is a common extension of pl, PZ and P3.

CHAPTER 4

Integration

In this chapter, we develop the theory of integration for real valued functions with respect to charges. Integration with respect to charges requires a good deal of tact, patience and circumspection to get around measurability problems. The treatment of this topic given here is fairly comprehensive. After presenting the preliminaries in the first three sections, we develop D-integral as presented by Dunford and Schwartz in Section 4.4. In Section 4.5, we introduce S-integrals which are of Stieltjes type and make comparisons with D-integrals. L,-spaces are introduced and studied in Section 4.6. Finally, in Section 4.7, ba(n, 9)is realized as a dual space.

4.1 TOTAL VARIATION AND OUTER CHARGES Let p be a charge defined on a field 9 of subsets of a set n. Recall the definitions of positive and negative variations, p + and p - , of p as expostulated in Section 2.5. p+(A)=Sup{p(B);BcA,B~fl,

A E ~ ,

and

@-(A)= -1nf {p(B);B c A, B ~ f l ,A E P .

As has been noted in Theorem 2.5.3, p + and p - are positive charges on g.The total variation lpl of p has been defined for bounded charges p on $. This notion can be introduced for any charge p. 4.1.1 Definition. For any charge p on a field 9 of subsets of a set 12, the total variation lp I of p is defined by

IF [(A)= p + ( ~+ )p - ( ~ ) , A E 9. Clearly, lp I is a positive charge on 2E lp I can also be described following way as in Theorem 2.2.4.

in the

86

T H E O R Y OF CHARGES

4.1.2 Theorem. For any charge A in 9,

p

on a field 9of subsets of a set R and

I~I(A)=sUP

f: Ip(Bi)l

i=l

holds true, where the supremum is taken over all partitions {Bt, B2, . . . , B,} of A in 9. Proof, If ~ ~ / ( A ) < cthen o , p is a bounded charge on the field A n 9 = { A n B; B E fl on A and the above equality follows from Theorem 2.2.4. If Ipl(A) = m, then either p+(A)= co or p-(A) = 00. From the definitions of p + and p - , it follows that SupCy=, Jp(Bi)l=a,where the supremum is taken over all partitions {B1,B2,. . . , B,} of A in 9. This proves the theorem. 0 Now, we introduce the concept of an outer charge.

4.1.3 Definition. Let 9be a field of subsets of a set SZ and p a positive charge on 9. The set function p * :P ( R ) [0, co] defined by --f

p*(A) = Inf {p(B);A c B, B E F}, is called the outer charge induced by

A cR

p.

The following proposition chronicles some of the properties of outer charges.

4.1.4 Proposition. Let F b e a field of subsets of a set SZ and p a positive charge on 9. Then the following are true. (i). p *(D)= 0. (ii). p *(A)s p*(B) if A c B c 0. (iii). p *(A) = p (A) if A E 9. (iv). p * ( A u B ) s p * ( A ) + p * ( B )if A, B c R . (v). I f 9 is a c+-field and p is a measure on 9, p*(Unat A,)S CnZlp*(A,) for any sequence A,, n 2 1 of subsets of R. Proof. Properties (i), (ii) and (iii) are obvious. To prove (iv), we proceed as follows. If either p*(A) = 00 or p*(B) = 00, the inequality obviously follows. Suppose p *(A)< co and p*(B) 0. There exist At, B1 in 9 such that A c A l , B c B t , p ( A l ) s p * ( A ) + & / 2 and p ( B t ) s p * ( B ) + ~ / 2 . Consequently, ~ * * ( A W B ) S ~ * * (=Ap ~ ( A~ lBu B ~ t) ) s p (AI)+ p (B,) s p *(A)+ p *(B) + E. Since E > 0 is arbitrary, the desired inequality follows. The proof of (v) is analogous to that of (iv). 0 4.1.5 Remark. Proposition 4.1.4(v) is not valid if 9 is only a field. Let R={1,2,3,. .. ,a}and 9 = { A ; either A or A" is a finite subset of

4.

87

INTEGRATION

{1,2,3, . . .}). Define p on 9 by p (A) = 0, = 1,

if A is a finite subset of {1,2,3, . . .}.

,

otherwise.

is a measure on the field 9. Note that p*({l,2 , 3 , . . .)) = 1. If we let A, = { n } ,n 2 1, then ps(Un2l A,,)= 1 and p*(A,,)= 0.

p

Finally, we end this section with a result on the outer charge induced by the sum of two charges. 4.1.6 Proposition. Let subsets of a set 0. Then

p1

and p2 be two positive charges on a field 9 of

(p1+pz)*=pT+CLK

Proof. It is obvious that ( p l + pz)*(A)2 p (A)+ p ; (A) for every A c a. If eitherp?(A)=ooorp:(A)=oo, then ( p 1 + p Z ) * ( A ) s p T ( ( A ) + p $ ( A is ) true. Assume that p (A)< oo and p: (A) < CO. Let E > 0. There exist B1, BZin 9 such that A c B1, A c BZ,

T

T

and ~ nB2)5 p ? (A)+ p: (A) + E . Since E > 0 Hence ( p I + pz)*(A)5 ( p +p2)(B1 is arbitrary, the result follows. 0

4.2

NULL SETS AND NULL FUNCTIONS

In this section, we formalize the notions of a null set and a null function. We first introduce the notion of a charge space. 4.2.1 Definition. A charge space is a triple (0,9 p ), , where R is a set, 9 is a field on R and p a charge on 9. 4.2.2 Definition. Let (R, 9,p ) be a charge space. A subset A of R is said to be a p-null set, or simply, a null set if p is understood, if lp ["(A)= 0.

The following properties of null sets follow from Proposition 4.1.4. 4.2.3 Proposition. Let (R, 9, p ) be a charge space. Then the following statements are true. (i). 0 is a null set. (ii). B is a null set if B c A and A is a null set.

88

THEORY OF CHARGES

(iii). u7-1A iis a null set if Al,A2,. . . , A, are null sets, where n is any positive integer. (iv). UnzlA, is a null set if A,, n 2 1 is a sequence of null sets, p is a measure and 9 is a a-field. The concept of a null set leads to the concept of a null function. Definitions. Let (R, 9, p ) be a charge space. (i). A real valued function f on R is said to be a p-null function, or simply a null function if p is understood, if

4.2.4

IP I*GJE a; If(w>l>E N = 0 for every E >O. (ii). Two real valued functions f and g defined on R are said to be equal almost everywhere iff - g is a null function. In this case, we use the notation f = g a.e.[~]. (iii). A real valued function f on R is said to be dominated almost everywhere by a real valued function g on R, if there exists a null function h on R such that f 5 g + h. In such a case, we use the notation f 5 g a.e.[p 3.

A sufficient condition for f 5 g a.e. [ p ] to hold is that lp I*({w E R; f ( w ) > g(w)})= 0 , though not necessary. The following proposition follows easily from Proposition 4.1.4.

Proposition. Let (R, 9, p ) be a charge space. The following statements are true. (i). cf +dg, IflP(p>0) and f g are null functions whenever f and g are null functions on R and c and d are real numbers. (ii). g is a null function if l g l s If I a.e. [ p ] and f is a null function. (5).For real fimctions f , g, h on R, f = h a.e. [ p ] whenever f = g a.e. [ p ] and g = h a.e. [ p ] . (iv). For real functions f l , f 2 , g l , g2 on R and c, d real numbers with f 1 = g l a.e. [ p ] and f 2 = g2 a.e. [ p ] ] cfi+df2=cgl-t-dg2 , a.e. [ p ] and I f l [ = lgll a.e. 4.2.5

[PI.

(v). On the space C(R, 9,p ) of all real functions on R, the binary relation defined by f g i f f = g a.e. [ p ] is an equivalence relation. (vi). For real functions f , g, h on R, f 5 h a.e. [ p ] whenever f 5 g a.e. [ p ] and g Ih a.e. [ p ] . (vii). A subset A of R is a null set if and only if I, is a null function. (viii). For real functions f , g on R, f = g a.e. [ p ] i f f 5 g a.e. [ p J and g f a.e. [ p ] .

-

-

4.2.6 Remark. If f l = g l a.e. [ p ] and f 2 = g2 a.e. [ p ] , it is not true that f i f 2 = g l g 2 a.e. [ p 1. It is not even true that f 2 = g 2 a.e. [ p ] iff = g a.e. [ p ] . The following example explains this.

4. INTEGRATION

89

Example. Let R = { l , 2 , 3 , . . .), 9 the finite-cofinite field on R and p the charge on 9 defined by p (A) = 0, if A is finite, = 1, if A is cofinite.

Letf a n d g o n R b e d e f i n e d b y f ( n ) = n + ( l / n ) , n 21 a n d g ( n ) = n - ( l / n ) , n 2 1. Then f = g a.e. [ p ] . But f z = g z a.e. [ p ] does not hold.

A sufficient condition for a real function f on R to be a null function is that lp I*({w E R; f ( w ) # 0 ) )= 0, though not necessary. The following proposition amplifies this point. 4.2.1 Proposition. Let (R, 9, p ) be a charge space. Let f be a real valued function defined on R. (i). I f IpI*({o E R; f ( w )# 0))= 0, then f is a null function. (ii). The converse of (i) is not true. (iii). If 9 is a u-field and p is a measure on 9, then f is a null function if and only if lp I*({w E R; f ( w )# 0 ) )= 0. Proof. (i). Note that for any E > 0, {oE

a;1f ( w ) l >

E}

c {w E R; f ( w ) # 0).

The monotonicity of Ip I* completes the proof. CL)be as in Remark 4.2.6. Let the function f on (ii). Example. Let (R, 9, R be defined by f ( n ) = l / n , n 21. Then f is a null function. For, {w E R ; If(w)I > E } is a finite set for any E >O. On the other hand, IpI*({w € 0; f (w 1 # 0))= 1. (iii). Observe that

u

E

>O

{WEn;If(o>l>E)=

u {OEn;If(w>l>l/n>

nzl

= { w E R; f ( w ) # 0).

By Proposition 4.2.3, the result follows.

0

Now, we come to the concept of essential boundedness.

4.2.8 Definition. Let (R, 9, p ) be a charge space and f a real valued function on R. f is said to be essentially bounded if there exists a null set A contained in R such that f is bounded on A'. Iff is essentially bounded, the essential supremum of f is denoted by (1film and is defined by

llfllm

= Inf SUP{If(w)l; w E A"),

where the infimum is taken over all null sets A contained in R. The following proposition gives equivalent conditions for essential boundedness of a function.

90

THEORY OF CHARGES

4.2.9 Proposition. Let (R,9, p ) be a charge space and f a real valued function on R. Then the following statements are equivalent. (i). f is essentially bounded. (ii). There exists k > 0 such that lp I*({w E R; If(w)I> k } ) = 0. (iii). There exists k > O such that If l Ik a.e. [ p ] . (iv). There exists a bounded function g on R such that f = g a.e. [ p ] . The following proposition gives the properties of essentially bounded functions which are easily established.

4.2.10 Proposition. Let (R,9,p) be a charge space. (All functions considered below are real valued functions on R.) (i). I f f and g are essentially bounded and c and d are real numbers, then cf + dg is essentially bounded. Further, (ii). 11f Ilm = 0 if and only i f f is a null function. (iii). I f f is essentially bounded and f = g a.e. [ k ] ,then g is essentially bounded and 11film = llgIlm. (iv). If B(R, 9,p ) is the collection of all essentially bounded functions on R, then the map 11 * llm :B(R, .fF, p ) + [0,00) is apseudo-norm on B(R, 9’’ p).

-

4.2.11 Remark. Introduce an equivalence relation on B(R, g, p ) by f g for f , g in B(R, 9, p ) iff = g a.e. [ p ] .Let Cm(R, 9,p ) be the collection of all equivalence classes of B(R, 9, p ) under -. For f in B(R, 9, p ) , let [f ] denote the equivalence class containing f . The map 11 Ilm :Cm(R, 9, p )+ [O, a) defined by Il[f]ilm = l\fllm for [ f ] in Cm(R, 9, p ) is a norm on cm(ag,p ).

-

The following concept of a simple function is important for the development of D-integral.

4.2.12 Definition. Let 9be a field of subsets of a set R. A real valued function f on R is said to be a simple function if it can be written in the form

f

=

c CiIFt

i=l

for some real numbers c l , c2, . . . ,c, ; F1, F z , . . . ,F , in 9with Fi nF j = 0 for every i # j and I Fi = R.

uY=

The following properties of simple functions are clear.

4.2.13 Proposition. Let 3 be a field of subsets of a set R. I f f and g are simple functions on R and c and d are real numbers, then cf +dg, f g and If Ip(p > 0 ) are all simple functions.

4.

INTEGRATION

91

Now, we introduce smooth functions.

4.2.14 Definition. Let (R, 9, p ) be a charge space. A real valued function f on R is said to be smooth if for every E > 0 there exists k > 0 such that IPI*hJE n ; If(u)l>kl)<E.

Not every function is a smooth function as the following example demonstrates.

4.2.15 Example. Let (0,9, p ) be as in Remark 4.2.6.The function f on R defined by f ( n )= n, n E R is not smooth. However, in some cases, many natural functions are smooth. In what follows, let 93 denote the Bore1 u-field on the real line R, i.e. 93 is the smallest u-field on R containing all subintervals of R.

4.2.16 Definition. Let (R, 9, p ) be a charge space in which 9is a cT-field A real valued function f on R is said to be on R and p a measure on 9. p-measurable if there exists a null set N c R such that f-'(B) n N'E 9 for every B in 93. 4.2.17 Proposition. Let (R, 9, p ) be a charge space in which 9 i s a u-field and p a real measure on 9. Then every p-measurable function f on R is smooth. Proof. Let N be a null set such that f-'(B) nN'f 9 for every B in 93. Let B, ={u ER;If(u)l?n}, n 2 1. Note that B,, n 2 1.10 . Since p is a real measure on the u-field 9,lpl is a bounded measure. Consequently, lim,,,Ip~(B, nN')=O. For any E >0, we can find a positive integer k such that IpI(BknN') < E . Now, observe that I c L I * ( B ~bL(*((Bk = n N ) u ( B k nN")) 5 Ip I*(Bk n N) + Ip I*(Bk n N')

51pl*(N)+IpI*(BknNc)
U

The following proposition records some of the properties of smooth functions.

4.2.18 Proposition. Let ( R , 9 , p ) be a charge space. (i). I f f and g are smooth functions on R and c and d are real numbers, then cf + dg, f g and I f I"( p > 0 ) are all smooth functions. (ii). I f f is essentially bounded, then f is smooth.

92

THEORY OF CHARGES

4.3 HAZY CONVERGENCE In this section, we introduce the notion of hazy convergence in the space of all real valued functions on R of a charge space ($ p )I . This ,$ notion , is commonly known as “convergence in measure” which is a misnomer in the present context of charges.

4.3.1 Definition. Let (a,9, p ) be a charge space. A sequence f n , n 2 1 of real valued functions on R is said to converge to a real valued function f on R hazily if lim l p l * ( { ~ ~ IR f n ;( W ) - f ( u ) I > E I ) = O

n-tw

for every

E

> 0.

The following proposition establishes that the limit function in hazy convergence is essentially unique.

Proposition. Let (R, 9,p ) be a charge space. If a sequence f,, n 2 1 of real valued functions on R converges to a real valued function f on R 4.3.2

hazily and f = g a.e. [ p ] , then f n , n L 1 converges to g hazily. Conversely, if f n , n 2 1 converges to both f and g hazily, then f = g a.e. [ p ] . Proof. For the first part, observe that for any E > 0, (W

lfn(W)-g(w)l>E)C{W

lfn(~)-f(~)I>~/2)

U { W En;

If(w)-g(w)l>E/21.

For the second part, observe that for any E > 0, {W

If(w)-g(W)I>E)C{W U{W

€0;I f n ( u ) - f ( a ) l > E / 2 ) Ifn(W)-g(W)I>E/2).

The monotonicity and the sub-additivity properties of lp I* complete the proof. 0 The following theorem gives algebraic properties of hazy convergence.

4.3.3 Theorem. Let (R, 9, w ) be a charge space. Let fn, n 2 1 and g,, n L 1 be two sequences of real valued functions on R converging hazily to real valued functions f and g on R respectively. Then the following statements are true. (i). cf, +dg,, n 2 1 converges to cf +dg hazily for any two real numbers c and d. (ii). If , I, n 2 1 converges to If I hazily.

4.

INTEGRATION

93

(iii). f:, n L 1converges to f’ hazily, i f f is a null function. (iv). fnh, n 2 1 converges to f h hazily, if h is a smooth function on R. (v). I f f is smooth and $ is a real valued continuous function defined on the real line, then $ ( f n ) , n 2 1 converges to $ ( f ) hazily. In particular, If n I p , n 2 1 converges to If Ip hazily for any p > 0. (vi). f,g,,, n 2 1 converges to f g hazily i f f and g are smooth functions. (vii). f:, n 2 1 converges to f’ and f i , n 2 1 converges to f - hazily. (viii). f n v g,, n 2 1 converges to f v g and f n A g,, n 2 1 converges to f A g hazily.

Proof. (i), (ii) and (iii) are easy to prove. (iv). Let E >O. Since h is a smooth function, there exists a real number k >0 such that Ip I*({w E R; Ih ( w ) ]> k } ) < ~ 1 2Since . f,, n L 1 converges to f hazily, there exists an integer m 2 1 such that IF I*({o E R; If n ( w ) - f ( w ) l > S / k } )< ~ / whenever 2 n 2 m, where S is a given positive number. So, if nzm,

IP I*({w

If n (0) h ( w ) - f ( w ) h (w )I > 6 ) ) 5 IP I*(b E 0;Iffl ( w ) - f (w)l Ih (w)l> 8,Ih (@)I 5 k } ) + IP I * ( b E a;I f n (0)- f (w)I Ih (0)I > 8,Ih (w )I > k } ) < IP I*({w E a;If n ( w ) - f ( w )I > ~ / k )+)~ / 2 E

< & / 2 + & / 2= E . This proves (iv). (v). Let E~ > 0 and E:! > 0. Since f is smooth, there exists a real number k > 0 such that Ip I*({w E R; If ( w ) l > k } )< ~ ~ / Since 2 . $ is uniformly continuous on [-2k, 2k], there exists S > 0 such that I $ ( x ) - $(y)l< ~2 whenever 1x1, IyI 5 2 k and Ix -yI < S . Without loss of generality, assume that S < k . Since f,, n 2 1 converges to f hazily, there exists m 2 1 such that lp I*({w E Q; If, ( w )-f ( w ) l > 8)) < e1/2 whenever n 2 m. Now, if n 2 m ,

IP I*({w E I $ ( f n (w 1) - (I,( f (w ))I > ~ 2 1 ) 5 IP I*({w E a;I $ ( f n ( w ) ) - $ ( f (w))I > E Z ~ If(w)l>kI) +I~l*({w +IPI*({W

I1Cl(fn(w)>-$(f(w))I>&*, E n ; I$(fn(w))-$(f(O))I>E2,

I f ( w ) l 5 k ,I f n ( w ) - f ( w ) I > S ) ) I f ( w ) l s k ,I f n b ) - f ( W ) I ~ S H

< E1/2+&1/2+0 = E l . Thus $ ( f , ) , n 2 1 converges to $(f) hazily. (vi). Observe that for any n 2 1,

94

THEORY OF CHARGES

Since f and g are smooth, f + g and f - g are smooth. See Proposition 2 4.2.18(i). By (i) and (v), ( f n +gn)2,n 2 1and ( f n -g,) ,n 2 1converge hazily to ( f + g ) 2 and ( f - g ) 2 respectively, Again, by (i), fngn, n 2 1 converges to fg hazily. and f- = $(f The assertion now fol(vii). Observe that 'f = i(f+ lows from (i) and (ii). f, v g, = f ( f , + g, + Ifn - g,l) and f, A g n = (viii). Observe that i(fn+gn-Ifn-gnI)for a l l n r l . 0

If[).

Ifl)

4.3.4 Remark. The assertion of Theorem 4 . 3 . 3 6 ~ is ) not valid unconditionally. We need to impose some conditions on h to ensure the hazy convergence of fnh, n 2 1 to fh. The following is a relevant example. Let (0,9, p ) be as in Remark 4.2.6. For n k 1, let fn

( k )= k, = 1-l/n,

if l s k s n , if k > n ;

f ( k )= 1

for all k in R;

h ( k )= k

for all k in R.

It can be checked easily that f n , n 2 1 converges to f hazily. But fnh, n 2 1 fails to converge to fh = h hazily. Let ( R , 9 , p ) be a charge space and C(n, 9, p ) the collection of all real valued functions on R. One can introduce a pseudo-metric p on C(R, .F,p ) such that convergence in the pseudo-metric space C(R, 9, p ) coincides with hazy convergence. p ) , Let For f in C(R, 9,

$(f, c 1 = c + Ip I * ( b E 0; If(w )I > cl),

c

> 0.

$(f, c ) is a nonnegative number and could be equal to 00. If p is bounded, then $(f,c) is a real number for all c > 0. Now, define

If $(f,c ) = 00 for every c > 0, we define llfll= 1. Now, we give the properties of the function 11 * 1 .

4.3.5 Proposition. The function I\.\\ defined on C(R, g,p ) above has the fdlo wing properties. = 0 if an d only i f f is a null function. (i). (ii). IF+gII 5 llfIl+llgll. (iii). The function p defined by p(f, g) = Ilf-gll for f, g in C(n, 9, p ) is a pseudo-metric on C(R, g,p ) .

]If]

4. INTEGRATION

95

(iv). fn, n L 1 converges to f hazily if and only if p ( f n ,f),n 2 1 converges to zero.

Proof. (i). If f is a null function, then +(f, c ) = c for every c > 0. Consequently ,

MI=

fril+c C

- 0.

Conversely, let llfll= 0. Let k be any positive number. In order to show that Ip I*({w E SZ; If(w)I > k } ) = 0, it suffices to show that lgl*({w E SZ; If(w)I > k } )< E for any 0 < E < k . Let 0 < E < k . Since llfll= 0, there exists c > O such that +(f, c ) / ( l ++(f, c ) ) < E / ( ~ + E ) . This implies that +(f, c ) < E . So, c < E and lp I*({w E SZ; I f ( @ ) [ > c } ) < E . Consequently, Ip I*({w E SZ; If(w)I >k } )I:IP I*(bE a;If(w)I > E ) ) 5 lp I*({w E a; I f ( w)I > c } ) < E . This shows that f is a null function. (ii). Observe that

= Inf r>O.s>O

Inf

I :

r>o,s>o

I Inf XI

+(f+g,r+s) l++(f+g, r+s)

+(f,r) $(g,s) l++(f,r) l++(g,s) +

+(f, r ) +Inf %4 $1 1 + +(f,r ) s>o 1 + +(g, s )

Ilfll+llgll.

I

(The first of the above inequalities can be proved as follows. The function y ( x ) = x / ( l +x), 0 I:X I:co is an increasing function having the additional property y ( x + y ) Iy ( x )+ y ( y ) for all 0 S X , y ICO. We use the convention that y(00) = 1. If c 1 = ICL I * ( b E ; If (w ) + g (w )I > r + sl), c2

=

I@I * ( b E a;If(w)I > r } )

and c3 =

IcLI*(b E a;Ig(0)l >sH,

then c1 I:c2+c3. Further,

96

THEORY OF CHARGES

From this, the first of the above inequalities follows. The rest of the equalities and inequalities are obvious.) (iii). This follows from (i) and (ii). (iv). Suppose fn, n 2 1 converges to f hazily. Then for any c > 0 and E > 0, there exists m L 1 such that IPI*({W

E n ;Ifn(W)-f(W)I>CH<E

whenever n L m. Consequently, for n L m,

C & C I---+-<-+&.

I+& l + c Consequently, lim p (fn, f)I c/(l + c ) + E . Since c > 0 is arbitrary, p ( f n , f)5 E . Since E > 0 is arbitrary, it follows that f n , we have lim n L 1 converges to f in the pseudo-metric space (C(R, $, p ) , p ) . l+c

Conversely, let p ( f n , f ) , n 2 1 converge to zero. Let k be any positive number. Let 0 < E < k be arbitrary. There exists m L 1 such that p(fn, f)< ~ / ( 1E+) whenever n L m.Now, let n L m be given. Since

This shows that fn, n L 1 converges to f hazily.

0

4.4 D-INTEGRAL In this section, we develop the basic ideas concerning D-integrals. We start with simple functions.

4.4.1 Definition. Let (R, 9, p ) be a charge space and f a simple function on R with a representationf = I:=,cJFifor some real numbers c1, CZ, . . . ,c, and partition {F,, F 2 .. . ,F,} of R in $, f is said to be D-integrable if Ip I(Fi)< CX, whenever ci # 0, and the D-integral of f, denoted by D 5 f dp, is defined to be the real number I;=, cip(Fi). (We adopt the convention = 0.) that 0 (*a)

4.

97

INTEGRATION

We settle the question of unambiguity of the above definition in the following proposition. Proposition. Let (a,.IF, p ) be a charge space. (i). Let f be a simple function with a representation f =ELl C ~ Ifor E ~some real numbers cl, c 2 , . . . ,cm and partition {El, Ez, . . . ,Em}of R in $such that lpl(Ei)
xi”=, ..

m

n

(ii). Kf f and g are D-integrable simple functions, then f + g is D-integrable and D j ( f + g ) d p = D j f d p + D j g d p . (iii). I f f is a D-integrable simple function and g is a simple function on 0 such that f = g a.e. [ p ] ,then g is D-integrable and D f d p = D 1g dp. then I$is also a (iv). I f f is a D-integrable simple function and E is in 9, D-integrable simple function. Proof. (i). Note that

This implies that ci = d j whenever EinFj#O. Suppose d j # O . Let J = (1 5 i 5 m ; Ei nFi # 0). If i E J, then ci # 0 and so [ pI(Ei)< a.Further, uis~ (Ei nFj) = F+ Consequently, lp J(Fj)< co. Also,

(ii). This is simple to prove. (iii). To prove this, it suffices to show that cip(Fi)= 0 whenever h = ciIFiis a simple and null function. We claim that for every 15 i 5 m either ci = 0 or p (Fi)= 0. Suppose ci # 0. Let E > 0 be any number such that E < Icil. Then {w E R: lh(w)l>E } = Uj., Fj, where J = { j ; 1 5j 5 m and

98

THEORY OF CHARGES

Icjl>~}. Obviously, i E J. Since h is a null function, IpI*(uj.J F j ) = l p l ( u j p FJ j ) = 0. Consequently, IpI(Fi)= 0. This proves (iii). (iv). The condition of Definition 4.4.1 for I$ is easily verified from the 0 hypothesis that f is D-integrable and simple. Part (iv) of the above proposition enables us to define D D-integrable simple function f and E in 9.

sEf d p for any

4.4.3 Definition. If f is a D-integrable simple function and E E 9, then D jEf d p stands for D 5 I$ dp. The following theorem gives the properties of integrals of simple functions.

-

4.4.4 Theorem. Let (R, 9, p ) be a charge space.

(i). I f f is a simple function on R and D-integrable with respect to p , then f is D-integrable with respect to p + and p - also. Further, for any E in 9, fdp+-D

J

fdp-. E

(ii). I f f and g are D-integrable simple functions on R, c and d are real numbers and E E 9, then cf + dg is a D-integrable simple function and

D

JE

(cf+dg)dp=c

(iii). I f f is a simple function on il and D-integrable with respect to p, then If l is a simple function on R which is D-integrable with respect to Ip I and for any E in 9

(iv). I f f is a D-integrable simple function on 9, i.e. I$? 0 a.e. [ p ] , then

and f 2 0 a.e.

(v). I f f and g are D-integrable simple functions on R and f E in 9, i.e. I $ s I E g a.e. [ p ] , then

(vi). I f f and g are D-integrable simple functions on R, then

[ p ] on

5g

If l ,

E in

a.e. [ p ] on

Igl,

If

+gl,

99

4. INTEGRATION

11f I - lgll are all D-integrable simple functions and for any E in 9,

(vii). Iffis a D-integrable simple function on R and c 5 f I d a.e. [ p ] on E in 9, i.e. c I ~ Id5 5 dIE a.e. [ p ] for some real numbers c and d, then c IP 103 5 D

I

E

f dlk I5dill. KE).

(viii). Iffis a D-integrable simple function on R, then the set function A on 9defined by c

A(F)=DJfdp,

F

E

~

F

is a bounded charge on 3? Also, IA [(F)= D 5, If l dlp 1, F E97 Further, A is absolutely continuous with respect to p in the following sense. Given E > 0, there exists S >0 such that \A (E)I < E whenever E E 9and Ip l(E)<8. Proof. Note that for simple functions f and g on a, f s g a.e. [ p ] if and only if Ip l({w E R; f ( w ) > g(w)}) = 0. (The set {w E 0;f ( w ) >g(w)} does belong to 9.With ) this observation, we proceed as follows. (i). Let f = ciIEi be a representation of f. Obviously, p+(Ei)< co and p-(Ei) < 03 whenever ci # 0. Hence f is D-integrable with respect to p + as well as with respect to p - . Further, if we let J = (1s i Im ;ci# 0}, then r

D

J

m

cip(Ei) = C cip(Ei)

f dp = i=l

i=l

xi"=,

ieJ

i=l

(ii). Letf = c i E andg , = dJF, be representations off andg respectively such that lp I(Ei)< co whenever ci # 0 and f pI(Fj) < co whenever dj # 0.

100

THEORY OF CHARGES

Then

Suppose cci + ddj # 0. Then, either cci # 0 or ddj # 0. This implies that either ci# 0 or d j # 0. This means that either IpI(Ei)
If1

(iv). We can assume that E = 0 and f is a simple function having a representation ELl ciIEiwhere each ciL 0. Now, (iv) is easily proved. (v). This is a consequence of (ii). and (iv). (vi). This follows from (iii) and (v). (vii). If Ip [(E)< 00, the result is clear. If Ip I(E) = 00, observe that c 5 0 5 d. (viii). A (0) = 0 since I& = 0. Let E and F be two disjoint sets in 9. Since IEvFf=I&+IFf, it follows that A(EuF)=A(E)+A(F). So, A is a charge Further, for any F in 9, on 9.

Thus A is bounded. Next, we show that IA [(F)= D 5, If1 dlp I for any F in 9. This, we proceed to establish in stages. Clearly, the result is true for f = Ia. Next, the result is clear for cIn also, for any real number c. If f=C:, ciIEi for some real numbers cl, c 2 , .. . , cm and El, E2,. . . , E m pairwise disjoint sets in 9, then A (F)= ELl ci D jF 1~~dp. Now, considering each D jFIEid p as a charge with reference to the charge space (Ei, Ei n9, p/Ei n and applying the above argument, we obtain the desired result for f. For the last part, if we let c = max {Icil;1 5i 5 m},then for any F in ,F, \A I(F)IIc Ip I(F). Consequently, A is absolutely continuous with respect 0 to p , We introduce two important concepts before defining the integrability of a general function.

4. INTEGRATION

101

4.4.5 Definition. Let (R, 9, p ) be a charge space. A real valued function on R is said to be TI-measurable if there exists a sequence f n , n z 1 of simple functions on R converging to f hazily.

If we denote the collection of all simple functions on by S(R, 9, p), then f is T1-measurable if and only i f f ES(SZ,9, p ) , where the closure is taken in the pseudo-metric space (C(n,$, p ) , p ) . See Proposition 4.3.5. 4.4.6 Definition. Let (R, 9, p ) be a charge space. A real valued function f on R is said to be Tz-measurable if for every E > 0, there exists a partition < E and If(w)-f(w’)I < E for {Fo,F1, FZ,. . .,F,} of 0 in 9such that lp ~(FO) every w , w ’ in Fi for every i = 1 , 2 , . . . ,n.

The following theorem establishes the relation between Tl-measurability and Tp-measurability. 4.4.7 Theorem. Let (R, g, p ) be a charge space. A real valued function f on R is T1-measurableif and only if it is Tp-measurable.

Proof. Suppose f is T1-measurable. Given E > 0, there exists a simple function g on such that J pI*({w E R; I f ( @ ) - g ( w ) l > ~ / 2 }<) E . Let g = cilEi be a representation of g. Let G = {w E R; If ( w ) - g ( w ) l > ~ / 2 } . Since Ip (*(G)= Inf {lp ((F);G c F, F E9 1, there exists Fo in 9 such that G c F o a n d I p I ( F o ) < e . L e t F i = E i n F & i = 1 , 2 , ..., m. Now,if l s i l m and o,U ’ E Fi, then If ( w )- g ( w ) l s ~ / 2If,( w ’ )- g ( w ’ ) l s ~ / and 2 g ( o ) = ci= g(w‘). Therefore,

zEl

If(w ) -f(w

’11 IIf(w ) - ci I+ lci -f(o ’)I 5

I f ( w >- g(w)l+ I f (a’)- g(w ’)I 5 E .

This shows that f is Tp-measurable. Conversely, let f be T2-measurable. For each n 2 1, let {Fno, Fnlr Fnz,. . . ,Fnk,}be a partition of n in 9such that Ip I(Fno) < l / n and If ( w ) f(w’)I < l / n for every w , w ’ in Fni and for every i = 1,2, . . . ,k,. For each n 2 1 and 1 Ii 5 k,, choose and fix wni in F,i. For each n 2 1, let k, fn

=

cf

i=l

+o

(wni)lFm,

*

IFn~*

Each f n is a simple function and f n , n 2 1 converges to f hazily. For, let E > O and m 2 1be such that l / m < E . If n L m , {w €0;I f , , ( o ) - f ( w ) I > ~ ) c F,o. Consequently, Ipl*({w en; I f n ( w ) - f ( w ) I > e } ) I I p I * ( F n o ) < l / n . This 0 establishes the result. 4.4.8

Corollary. Every TI-measurablefunction is smooth.

102

THEORY OF CHARGES

Proof. From the definition of T2-measurability, observe that every T2measurable function is smooth. The result now follows from Theorem 4.4.7. 0 Relations between TI-measurable functions, Smooth functions and bounded functions can be described as follows, T1-measurable function

%\Smooth function 4.4.9 Corollary. Let (a,9,p ) be a charge space. (i). I f f and g are TI-measurable functions on SZ and c and d are real numbers, then cf + dg and f g are all TI-measurable. (ii). If I,4 is a real valued continuous function defined on the real line and f is TI-measurable,then I++( f ) is TI-measurable. In particular, I f 1’ ( p > 0 ) is TI-measurable i f f is T1-measurable. (iii). If f n , n 2 1 is a sequence of TI-measurable functions converging to f hazily, then f is T1-measurable and fcl(fn), n 2 1 converges to $ ( f ) hazily, where I,4 is as in (ii).

Proof. (i) and (ii) follow from Corollary 4.4.8 and Theorem 4.3.3(i) and (vi). (iii) follows from the Remark following Definition 4.4.5, Theorem 4.3.3(v) and Corollary 4.4.8. The following proposition is instrumental in establishing the unambiguity in the general definition of D-integral. 4.4.10 Proposition. Let (a,9,p ) be a charge space. Let f n l , n 2 1 and f n 2 , n 2 1 be two sequences of D-integrable simple functions on SZ converging to a real valued function f on R hazily. Suppose

for i = 1,2. Then D JE f n i d p converges uniformly over E in 9 for each i = 1, 2, and the limits coincide. Proof. By Proposition 4.4.4(iii), for any m , n 2 1 and i = 1, 2

for every E in 9. Consequently, D jEfni dp, n 2 1converges uniformly over E in 9for each i = 1, 2. It remains to be shown that for each E in 9, fnl

d p = lim D n-tm

f n z dp.

4.

103

INTEGRATION

This is carried out in the following steps. 1". Let g , = l f n ~ - f n 2 1 , n 2 1, and p , ( F ) = D jFgndlpl for F in 9and y1 2 1. Each pn is a positive bounded charge on 9. 2". We claim that p,, n 2 1 converges uniformly over 9. For any F in 9 and n, rn 2 1, by Theorem 4.4.4(vi),

5~

J

Ifnl-frnlI

dIFI+D

I

Ifnz-frnzl

dbI-

Thus the From this, it follows that p,, n 2 1 is uniformly Cauchy over 9. claim is established. 3". Let A(F)=lim,,+mpn(F), F E ~It .suffices to show that A = O . For, for any E in 9,

If

p,(E) = 0, then

4". Now, we claim that A is absolutely continuous with respect to p. (See Theorem 4.4.4(viii).) Let E >O. There exists N 2 1 such that ]k,(E)-A (E)(< ~ / for 2 every E in 9 and n 2N.Since p N is absolutely continuous with respect to p, there exists S > O such that ~ N ( E<)~ / 2 whenever E E 9and lp [(E)< S. Consequently, if E E 9and Ip ((E)< 6,then A(E)SIh(E)-pN(E)1+pN(E)<&/2+~/2 =E. 5". The above deliberations can be summarized as follows. Let E > 0. There exists S > 0 and N 2 1 such that A (E) < E whenever E E 9 and Ip I(E)< S, and [A (F)- pn(F)I< E for every F in 9and for every n L N. 6". We show that A ( 0 ) < 4 ~ .Let A'={w ~n;g,(o)=O}. Since g N is a simple function, A'E 9.Since gN is D-integrable, Ip,I(A)< 00. Also pN(A') = 0. From 5", we conclude that A (A') < E . If lp l(A) = 0, then A (A) = 0 and A (0)= A (A)+ A (A') < E < 4 ~ The . next step covers the case when IP KA) > 0.

104

THEORY OF CHARGES

7". Suppose Ip \(A)> 0. Since g,, n z 1 converges to 0 hazily, there exists an integer N 1> N such that lp I*({w E 0; lgn(w)I> ](A)})< S whenever n z N l . Let B" = {w E 0;IgNI(w)I> E / I ~ ~ ( A )Since } . gN1is a simple function, P B'E 3.Further, if w E B, then IgN1(w)I 5 E / ~ I(A). 8".

A (a) = A ( A n B)+A ( A n B')+ A (A")

<[pNI(A ~ B ) + E ] + +EE . The inequality A ( A n B') < E follows from the following argument. By 7", lp 1(A nB") 5 lp [(B")= Ip I*(B') < 8. So, by 5", the above inequality follows. Again, by 5", the inequality A ( A n B)

Consequently, A (R) < 4.5. Since E > 0 is arbitrary, it follows that A (0)= 0. SinceA isapositivecharge,wehavethatA = 0.Thiscompletestheproof. 0 Now, we are in a position to define D-integrability of a general function.

4.4.11 Definition. Let (R, 9, p ) be a charge space. A real valued function f on R is said to be D-integrable if there exists a sequence f n , n Z 1 of D-integrable simple functions on such that (i). f n , n 2 1 converges to f hazily. 69. limm.,+m D J I f n -f m l dJpI= 0. Iff is D-integrable, the D-integral off is denoted by D J f d p and is defined to be the number limn+mD J f n d p . The sequence f n , n 2 1 is called a determining sequence of D-integrable simple functions for f , or simply a determining sequence for f . From Proposition 4.4.10, it is clear that limn,m D J f n d p exists and is finite, and is independent of the choice of the determining sequence fn, n 2 1. Also, observe that every D-integrable function is TI-measurable. Iff is D-integrable and E E 3,then the function I& is also D-integrable. If f n , n 2 1 is a determining sequence of D-integrable simple functions for f, it is easily checked that Id,,, n 2 1 is a determining sequence of Dintegrable simple functions for I&,. Consequently, we define D 5, f d p = D JkfdCL. We need a lemma which will be useful in the proof of Theorem 4.4.13(xi). 4.4.12 Lemma. Let ( a , F , p )be a charge space and f a D-integrable function. Let f n , n 2 1 be a determining sequence for f. Then f , -f is Dintegrable for every n L 1 and

lim D n-m

J

Ifn-fldlpl=O.

105

4. INTEGRATION

Proof. Fix n 2 1. Then fn -fm, m 2 1 converges to f n -f hazily. Further, each f,, -fm is a D-integrable simple function. Also, limm,p+m D I( fn -f m ) (fn -fp)l dJpI= 0. Hence f n -f is D-integrable, and Ifn -fml, m L 1 is a determining sequence for If,,-f I. Thus lim D

n-m

J

lfn-fJdlp/=lim n-tm =

[ Iim D J Ifn-fmIdl~I] m-m

lim D I Ifn-fmldlpl=O.

m,n+m

This proves the lemma. Now, we give a comprehensive list of properties of D-integrable functions. 4.4.13 Theorem. Let (R, 9, p ) be a charge space. (i). If a real valued function f on R is D-integrable with respect to p, then f is D-integrable with respect to p + as well as with respect to p - . Further, for every E in 9,

D [ E f d p = D /E f d p + - D (ii). Iffand g are D-integrable and c and d are real numbers, then cf+dg is D-integrable and for every E in .F,

(iii). Iff is D-integrable with respect to p, then If1 is D-integrable with and for any E in 9, respect to p as weEl as with respect to

(iv). f is D-integrable if and only iff' and f- are D-integrable. Further, if f is D-integrable, then D / E f d p = D IE f ' d p - D j

E

f-dp

for every E in 9. More generally, iff and g are D-integrable, then f v g and f A g are D-integrable and g d p = D [ E ( f v g ) d p + + DJE(fAg)dlr for every E in 9.

106

THEORY OF CHARGES

(v). I f f is D-integrable and f

20

a.e. [ p ] on E in g, i.e. I j r 0 a.e. [ p ] ]then ,

(vi). I f f and g are D-integrable and f I g a.e. [ p ] on E in 9, i.e. I J s I E g a.e. [ p ] , then

(vii). I f f is D-integrable and c ~f numbers c and d, then

Id

ClFI(E)SD E

a.e. [ p ] on E in 9for some real

f dlCLIsdlll.I(E).

In fact, if c > 0 , then Ip I(E)< 00. (viii). I f f and g are D-integrable and E E 9, then

(ix). f is a null function if and only i f f is D-integrable and I f I dlp I = 0. (x). If f is D-integrable and g = f a.e. [ p ] ] ,then g is D-integrable and D jE f d p = D 5, g dp for all E in 9. (xi). I f f is D-integrable, then the set function A on $defined by

A(F)=D

[ f dp,

F

E

~

F

is a bounded charge on 9satisfying IAl(F)=D[F I f l d l p l ,

FE$.

Further, A is absolutely continuous with respect to p in the following sense. Given E > O , there exists 6 > O such that IA(E)I < E whenever E E and~ IF I(E)<6.

4.

107

INTEGRATION

(xii). If p is positive, f is D-integrable and A is the charge on $defined by IFf dp, F E 9, then

A (F)= D

f'dp

and A-(F)=D

f-dp IF

for all F in 9. (xiii). For a D-integrable function f, D I 1f 1 dlp 1 = 0 if and only if D 5, f d p = 0 for every E in $. Iffand g are D-integrable, then f = g a.e. [ p ] if and only if

for every E in $. Proof. (i). If fn, n 2 1 is a determining sequence for f with respect to p, then it has the same property with respect to Jpl,p + and p - . This follows from the inequalities that pfslpI and p - s l p l . Consequently, f is Dintegrable with respect to p + as well as with respect to p - . By Theorem 4.4.4(i), we have for any E in g,

D

f d p = n-m lim D = lim n+m

D

JE

fn

JE

fn

d p = n+cC lim [D

JEfn

d p + - lim D

I,

n+m

dp+-D

J

fn

dp-1

E

fn

dpc-

(ii). This follows from Theorem 4.3.3(i) and Theorem 4.4.4(ii). (iii). If fn, n 2 1 is a determining sequence €or f with respect to p, then 1fnl, n 2 1 is a determining sequence for 1f l with respect to p as well as withsrespect to ( p ( .This follows from Theorem 4.3.3(ii) and Theorem 4.4.4(vi). Further, from Theorem 4.4.4(iii),

= D lE IfldlPl for any E in 9. (iv). If f n , n 2 1 is a determining sequence for f, g , n 1 1 is a determining sequence for g, then fn v g,, n 5 1 converges to f v g hazily, by Theorem

108

THEORY OF CHARGES

4.3.3 (viii). Further,

(Note that \(a v 6) -(c v d ) l s (a- c l + (6- d ( and ( ( aA 6) - (C ~ d 5 ) ((a-c(+ Ib - dl for any numbers a , 6, c and d.) Hence f, v g,, n z 1 is a determining sequence forf v g. Similarly, one can show that f, A g,, n I1is a determining sequence for f A g. Since f + g = (f v g ) + (f A g), by (ii), we have D ,j (f+ g ) d p = D j E ( f v g ) d p + D j E ( f A g ) d pf o r a n y E i n P . T a k i n g g = O , w e get the first part of (iv). 0I a.e. [ p ] ,there exists a null function h such that h +I&z 0. (v). Since I& If fa, n L 1 is a determining sequence for f,then Id,, n z 1 is a determining sequence for h +I&. See Proposition 4.3.2. Hence h +I& is D-integrable, and (I&,,)+, n L 1 is a determining sequence for ( h +I&)+= h +I& with respect to lp I. Since f: 2 0 for every n L 1, by Theorem 4.4.4(iv), and (ii) and (iii) above, we have

= lim n+w

D J (I&,)+ dlp 1 2 0.

This proves (v). (vi). This is a consequence of (v) if one looks at the function IE(g -f). (vii). If lp I(E)
for all m, n 2 1. Hence f,,A c, n L 1 is a determining sequence for the constant function c. Hence the constant function c is D-integrable. But = m. This shows that c s 0. Hence, it follows this is not possible since JpJ(f2) dip]. If Ipl(E)= co, we can show that d L 0 by an that cIpl(E) ID analogous argument. Thus the desired inequalities are established for all cases.

If

4.

109

INTEGRATION

(viii). This is a consequence of Theorem 4.4.4(vi). (ix). Iff is a null function, it is easily verified that 0, 0, . . . is a determining sequence for f and hence D j If1 dlp I = 0. Conversely, let f be D-integrable and D 5 dlp I = 0. Let f,, n z 1 be a determining sequence for f. Then limn+mD 5 lfnl dlpLJ=0. For any S>O and n z l , let E , ( S ) = ( w ~ f l ; lfn(w)1>6) and F,(S)= {w E a; ( w ) -f(o)I> 8). Since f n is a simple function, E,(S) E 9.Since f,, is D-integrable, lp I(E,(S)) < 00. Further, for any n 2 1, by (vi) and (vii),

If1

If,

D

J

lfnl

J'

dlp12~

lfnl

dlpl2SlpI(En(S))*

E"(6)

Consequently, limn+mIp J(E,(S))= 0. Since f,, n 2 1 converges to f hazily, Ipl*(F,(S)) = 0. Thus, for any n 2 1,

IF I*({w E a;If(w )I > 26)) 5 I@I*({w E a;Ifn (w )I >6)) + IP I*({w E a;Ifn(w> -f(w>l>

6))

which converges to zero as n tends to co.Consequently, Ip I*({w E R; If(w)I > 28)) = 0 for any 6 > 0. Hence f is a null function. (x). This follows from (ix) and (ii). (xi). It is now obvious that A is a charge. The boundedness of A follows from IA (F)I= ID jFf d p J5 D If1 dlpl s D I If1 dlp 1 for any F in 9. Now, we show that \Al(F)= D SF I f ] d1p1 for every F in 9. Let f,, n 2 1 be a determining sequence for f. Let A,, n z 1 be defined by A,(E) = D IEfn dp, E E 9. We show that limn.+mIA,l(E) = IA [(E)for every E in 9. Then, by Theorem 4.4.4(viii), and (ii) above, we would have

IF

Let F E 9be fixed and E > 0. Since fn, n 2 1is a determining for every E in 9. sequence for f, by Lemma 4.4.12, there exists N 2 1 such that D SF [fdlp 1 < E whenever n 2 N. Let {Fl,F2, . . . , Fk} be any partition of F in 9. Then for any n 2 N ,

I,f

110

THEORY OF CHARGES

We show that for any n 2 N , I lA,l(F) - [A I(F)I < 3.5. Let n 2 N be fixed. From the definition of IA,l(F) and IA I(F), we can find a partition {Al, AZ,. . . ,Am} of F in 9and a partition {B1,B2,. . . ,Bk}of F in 9such that

and k

k

lAnl(F)-

i=l

lAn(Bi)l=lAnl(F)-

i=l

ID /

Bi

f n dpl <&.

LetFij=AinBj,I s i s m a n d l s j s k . T h e n { F i j ; l s i s r n a n d l s j s k } Further, is a partition of F in 9.

and

Therefore, for n 2 N,

<&

+ E +&

=3E.

This completes the proof of the desired assertion. Now, we prove that A is absolutely continuous with respect to p. Let E > 0. By Lemma 4.4.12, there exists a D-integrable simple function g such that D If-gl dlpl < E . Let M be a positive number such that lg(u)I s M for every u in SZ. Take 6 = E/M.Let E E 9and Ipl(E)< 6. Then

J

E

s~ If-gIdlpI+MIpl(E)<&+M-=2~. M

4.

INTEGRATION

111

This shows that A is absolutely continuous with respect to p. (xii). From Theorem 2.2.2(5), A + =$(A + IA I) and A - = +(A - IA I) for the bounded charge A. Then,

= D j f'dy. F

Similarly, the result about A - is proved. if D J F f d p = 0 (xiii). Let A (F)= D l, f dp. Then A (F)= 0 for all F in 9, for all F in 9.Hence [A I(R) = 0. So, by (xii) above, we have D 5 I f l dlp I = 0. The converse is clear. Now, the second part follows from the first part and (ix). This completes the proof of the theorem. Now, we enumerate all the D-integrable functions for the simple example given below.

Example. Let (R, 9, p ) be a charge space in which p is a 0-1 valued charge on 9.A real valued function f on R is D-integrable if and only i f f = c a.e. [ p ] , where c is a constant, and i f f = c a.e. [ p ] ] ,then Djfdp=c. 4.4.14

Proof. Since p is bounded, every constant function c is D-integrable. By Theorem 4.4.13(x), any function f which satisfies f = c a.e. [ p ] for some constant c is D-integrable and D 5 f d p = c. Conversely, suppose f is D-integrable. Let f,, n 2 1 be a determining sequence for f . Since each f , is a simple function and p is a 0-1 valued charge, f , = c, a.e. [ p ] for some constant c,. Without loss of generality, we can assume that f, =c, for every n 2 1. Note that c,, n 2 1 is a Cauchy sequence of real numbers since D If , -f , I d p = Jc, - c, I which converges c,. Then to zero as n, m + co. Let c =

We show that f = c a.e. [ p ] .Let E > 0. Let N 1L 1 be such that Ic, - c I < ~ / 2 for every n r N 1 .Since f,, n 2 1 converges to f hazily, there exists N2r1 such that p *({w E R; I f , ( w ) -f(w)I > ~ / 2 } = ) 0 for every n LN2. Let N = max { N I ,Nz}. If n LN, then p * ((0E R; If (0)- c I > E }) 5 p * ( { w E R; If (w ) f,(w)I > .5/2}+p*({w E R; If,(w) - c J > ~ / 2 } 5 ) O + 0 = 0. Hence f = c a.e. [PI.

The following three lemmas are needed to prove Theorem 4.4.18.

0

112

THEORY OF CHARGES

4.4.15 Lemma. Let (R, 3,p ) be a charge space and f a D-integrable function on R. Let A on 9 be defined by A (F)= D jF f d+, F E 9.Then given E > 0, there exists A in 9 s u c h that I+ [(A) < co and IA [(A')< E .

Proof. By Lemma 4.4.12, there exists a D-integrable simple function f on R such that D J lg -f I dlp I < E . Let A' = {w E R; g ( w ) = 0). Since g is a simple function, A' E 9. Since g is D-integrable lp I(A)< 00. Further,

CD

J

If-gldlpI+O<E.

0

This completes the proof.

4.4.16 Lemma. Let (R, 9, p ) be a charge space and f a D-integrable function. Suppose g is a simple function and I g l s l f i a.e. [ p ] . Then g is D- integrable.

0

Proof. This follows from Theorem 4.4.13(vii).

4.4.17 Lemma. Let (R, 9, p ) be a charge space. Let g,, n 2 1 be a sequence of simple functions converging to g hazily. Then there exists a sequence h,, n 2 1 of simple functions converging to g hazily such that lhnis 2 ( g ]for every n21.

Proof. From the definition of hazy convergence, we can find a subsequence g,,, k 2 1of g,, n 2 1 such that ]pl*({w E R; lgnk(w)1> l / k ) )< l / k for every k r 1 . Consequently, we can find Ak in 9 such that I p I ( A k ) < l / k and { w E S 1 ; I g n , ( w ) - g ( w ) l > l / k } c A k for every k r l . So, if ~ E A Cthen ~, ]g,,(w) -g(w)l< l / k for every k 2 1. Now, for each k 2 1 , define hk(W)=gnk(w), if w E A C k and lgnk(w)I> 2 / k , = 0, otherwise. Since each g,, is a simple function, each hk is a simple function. Let w E ACk and satisfy the inequality Ig,,(w)l > 2 / k . Then Ihk(w)I= lgnk(U)l 5 Ignk(w)-g(w)I+Ig(w)I 5(1/k)+Ig(w)I* But I l k rlgnk(w)I-Ig(w)I> 2 / k -Ig(w)l. Therefore, Ig(w)l> l / k . Consequently, ]hk(w)I5 l / k +lg(w)l<2lg(w)I.Thus, for any w in S1, Ihk(w)ls2]g(w)Ifor all k 2 1 . Now, we show that hk, k r 1 converges to g hazily. Let E > 0. Then there exists N 2 1 such that 1 / N < E . If k r N, then

I*

((0 E

; Ihk (w - g (w )I > E 1) IF I* ({w E A

k

; Ihk (w

- g (w )I > E 1)

Ihk(W)-g(w)l>E)) S IpI(Ak)+o < l / k . 0 Hence hk, k 2 1 converges to g hazily. +Ip]*({w

113

4. INTEGRATION

The following theorem gives a necessary and sufficient condition under which a given function dominated by a D-integrable function is Dintegrable. 4.4.18 Theorem. Let (R, 9, p ) be a charge space. Let f and g be two real valuedfunctions on R such that l g l s a.e. [ p ] and f is D-integrable. Then g is D-integrable if and only if g is TI-measurable.

If1

Proof. “Only if” part follows from the definition of D-integrability. “If” part. Suppose that g is TI-measurable. By Lemma 4.4.17, there exists a sequence h,, n 2 1 of simple functions converging to g hazily and such that lhn1s21gl for every n r l . Since each lhn1s21f1 and f is Dintegrable, by Lemma 4.4.16, we have that h, is D-integrable. Now, we show that limm,n+oO D J Ih, - hml dlp I = 0. Given E > 0, we exhibit N L 1 such that D Ih, - h, Idlp I < 3.5 for every n, m 2 N . Observe that for every n, m 2 1 and E in 9, D JE Ih, -hml d l p l 5 4 D 1, dlpl. L e t s > O . ByLemma4.4.15, thereexistsaset A i n 9 s u c h that IpI(A)
If1

D

I

Ihn -hml dlpl = D

I

Ihn -hml dlpl + D

A

I,.

Ihn -hmI dIpI

0, we proceed as follows. By Theorem 4.4.13(xi), there exists S > O such that 4D 1, dip( < E whenever E E F and Ip [(E)< S . This implies that D JE Ih, -hm 1 dlp 1 < E whenever E E 9 and /pl(E)< S . Since limm,n+oo IpI*({w E R; Ih,(w) hm(w)l>&/IpI(A)})= 0 , there exists N I1 and sets En, in 9 for n, m r N suchthatIpI(E,,)<S andIh,(w)-h,(w)l sE/Ipl(A)ifw EEC,,forn,m 2 N . Now, let n, m rN. Then

If1

This shows that h,, n 2 1 is a determining sequence for g. Hence g is D-integrable. 0 p ) be a charge space and f a T1-nteasurable 4.4.19 Corollary. Let (R, 9, function on R. Then f is D-integrable if and only i f I is D-integrable.

fl

114

THEORY OF CHARGES

The following theorem is an extension of Lemma 4.4.12.

(a,

4.4.20 Theorem. Let 9, p ) be a charge space and f,, n 2 1 a sequence of D-integrable functions such that

lim D m,n-co

J Ifn-fmldlpl=O.

Let f be a real valued function on R such that fn, n z 1converges to f hazily. Then f is D-integrable an d lim D n-a,

J Ifn-fldlpl=O.

Proof. If fn's are simple functions, the assertion follows from the definition of D-integrability off and by Lemma 4.4.12. Since f n is D-integrable, by Lemma 4.4.12, there exists a D-integrable simple function h, on R such that D

Ifn-hnIdIpI
and

IP I*({w E a;Ifn(w)-hn(w)I>

l/n>)
for every n L 1. We claim that h,, n z 1 converges to f hazily. Let E >O. Since f,, n z 1 converges to f hazily, there exists N1L 1 such that IE.L I*({w E R; If n ( w ) -f(w)l> ~ / 2 } < ) ~ / whenever 2 n 2 N1. Let N L 1 be such that 1/N < ~ / 2and N L N ~If. n rN, then

( ~ € Ihn(o)-f(U)l>E)C{U 0;

Ihn(w)-fn(w)l>~/2)

4.J

Ifnb)-f(W)I>E/2)

€0;Ihn(w)-fn(w)l>l/n) u{w

€02If"(W)--f(dI>EI2). ;

From these set inclusions, it follows that IpI*({w ER; I h , ( w ) - f ( w ) l > ~ } ) < : ~ / 2 + ~ / 2 = ~

whenever n LN. Next, observe that

+D

J Ifm-hmldl/l.l

for all m, n z 1. From this, it follows that limn.m+a,D 5 )h, -hml dip( = 0.

4.

INTEGRATION

115

Hence h,, n 2 1 is a determining sequence for f . So, f is D-integrable. Further, for n 2 1,

The second term on the right above converges to zero as n + CO, by Lemma 4.4.12. Hence lim D n+m

I Ifn

-f

I dlp I = 0.

This completes the proof.

4.5

S-INTEGRAL

In this section, we introduce S-integrals which are of Stieltjes type in the framework of charge spaces. We also show that D-integrals and Sintegrals coincide in the case of positive bounded charges and bounded functions. I n what follows, we assume that all the charges are positive bounded unless otherwise specified. For a given field 9 on a set R, let 8 denote the collection of all finite partitions of R in 9. On 8, we define a partial order by PI 2 P2 for PI, PZ in 8 if PI is a refinement of P2, i.e. every set in P2 is a union of sets in PI. Indeed, ( 8 , ~ is a)directed set. 4.5.1 Definition. Let ( R , 9 , p ) be a charge space. Let f be a bounded real valued function on R. For P = {Fl, F2, . . ,F,} in 8, let

.

and

L(P) is called the lower sum associated with P and U(P) is called the upper sum associated with P. (Since f and p are bounded, L(P) and U(P) are real numbers.) The following proposition gives some inequalities between these sums.

Proposition. Let (R, 9,p ) be a charge space and f a bounded real valued function on R. Then for any PI L P in ~ 8) 4.5.2

116

THEORY OF CHARGES

Proof. Since P 1 z P Z , every set in Pz is a union of sets in PI. Hence the above inequalities easily follow. Of course, we use the fact that p is positive in proving the above inequalities. Thus, we observe that the net {U(P);P E P} defined on the directed set (9,L) is a decreasing net of real numbers bounded below and hence has a limit. The net {L(P); P E 9)defined over the directed set ( 9 ,is~an) increasing net of real numbers bounded above and therefore, has a limit.

4.5.3 Definitions. Let (fl, 9, p ) be a charge space and f a bounded real valued function on R. Let

J

f d p = Inf U(P) = lim U(P) PEP

PEP

and

-

f d p = Sup L(P) = lim L(P). PE B

-

j f d p is called the upper integral of f with respect to

p

and

5f

d p the

lower integral off with respect to p. The following proposition is obvious in view of Proposition 4.5.2.

4.5.4 Proposition. Let (fl, 9, p ) be a charge space and f a bounded real valued function on fl. Then

Now, we define the S-integral.

4.5.5 Definition. Let (O,?F, p ) be a charge space and f a bounded real valued function on fl. f is said to be S-integrable if

If f is S-integrable, the S-integral of f is denoted by S I f d p and is

-

defined to be the common number 5 f d p = f d p . -

4.5.6 Remark. I f f is a simple function, then S j f d p = D f d p .

117

4. INTEGRATION

We link S-integrability and D-integrability of a function in the following result. 4.5.7 Theorem. Let (a, 9, t ~ be ) a charge space and f a bounded real valued function on Q. Then the following statements are equivalent. (i). f is TI-measurable. (ii). f is T2-measurable. (iii). f is S-integrable. (iv). There exists a real number a with the following property. For every E >0, there exists a partition Po in B such that for every partition P in B with P = {Fl, F2, . . . , F,} 2 POand for every wi in Fi, i = 1 , 2 , . . . , n,

holds. (v). For every E > 0, there exists a partition Po in B such that for every partition P in 9 with P ={F1, F 2 , . . . , F,}?Po and for every w i l , wi2 in Fi, i = l , 2, .. . , n ,

IC

I

I n

i = l ( f ( w i i ) - f ( W i Z ) ) ~ ( F i ) l< E

holds. (vi). For every E >0 , there exists a partition Po in B such that for every partition P in 9 with P = { F I , F2, . . . ,F,) 2 PO,

i[

i=l

SUP

If(wi1)-f(Wi2)11tL

(Fi) < E

w,l,w,zeFi

holds. (vii). For every E > 0 , there exists a partition PO= { E l , E2. . . . ,E m } in $9’ such that for any partition { E l l , E12,. . . , Elkl, E21, E22,.. ., E2k2,. .., Eml, Em2,. . ., Emk,} in 9 with E i = U f ~ , E i i , i = 1, 2, . . . ,m and for every choice Aii, j = 1 , 2 , . . . , ki, i = 1 , 2 , . . . ,m, of real numbers satisfying

holds. (viii). f is D-integrable.

118

THEORY OF CHARGES

Proof. (i)+(ii). This follows from Theorem 4.4.7. (ii) (iii). Let E > 0. We show that

+

This then would prove that f is S-integrable. Let M = SupwEnlf(w)l. Since f is Tz-measurable, there exists a partition P = {Fo,F1, Fz, . . . ,F,} in 9 such that p(Fo)<&/4M and

If(wil)-f(wiz)I

<~/2~((n>

for every oil,wi2 in Fi for i = 1 , 2 , . . . , m.Then

< &/2+ &/2= e. This shows that f is S-integrable. -

(iii)J(iv). Let a = S Jfd p = f dk

=

J f dp. Let

-

E

> 0. There exists a

partition POin P such that for every P z Po, U(P)- a < E and a - L(P) < 8. Let P = {FI,Fz, . . . ,F,} be any partition in 9 such that P z PO.Let wi in Fi, i = 1, 2, . . . ,YE be arbitrary. Then n

n

C f(Wi)P(Fi)-a i=l

5

C (Supf(w))P(Fi)-a

i=l

w€Fi

=U(P)-a

<&,

and "

n

= a -L(P)

<&.

119

4. INTEGRATION

\xy=l

Consequently, f(wi)p(Fi) - a\ < E . This proves (iv). (iv).$(v). This is obvious. ( v) j ( vi ) . This is obvious. The modulus sign can be taken inside the summation in (v) and the inequality still remains valid. (vi) (vii). This is obvious. (vii)j(viii). For each k L 1, let P k = {Ekl,Ek2,.. . , E k p k } be a partition in B satisfying (vii) for E = l/k. Assume, without loss of generality, that P I I P ~ S P* ~. ~For. each k 2 1 and i = 1,2,. . . , p k , choose and fix Wki in E k i . Let

+

pk fk

=

k

f(wki)IEk,, i=l

2

1.

We claim that limm,k+ao D Ifm -fkl d p = 0. To begin with, we look at the function Ifk -fml. Suppose m 2 k. Since P k < P m , every set in P k is a union of sets in Pm.Assume, without loss of generality, that the sets in P k are of the following form. E k l = E m l U E m Z U * * *uEmrl, E k 2 = Emr1+1 U E m r l + 2 u * * u Emr2,

.............................. Ekpk

= EmrPk-l+1 u Emrpk-l+2

U

* * *

u Emp,,,.

Write ro = 0 and rpk= pm. Then

IC pk

Ifk

-fml

p, f(Wki)IEki

i=l

pk

1c Pk

f(wmi)IE,,,iI i=l

P,

i‘

C 1 = (i-1 j=ri-1+1 = i-1

-

f(Uki)IE,,

-

1f ( w m i ) I E , i l

i=l

‘i

j = ri - l + l

(f(wki)-f(Omj))lE,jI.

Therefore,

D

I

pk Ifk-fml

dp =

‘8

C C i =1j = ri

I+

If(wki)-f(wmj)lp(Emj). 1

Obviously, If(Wki) -f(wrnj)l = Aii 5 S U ~ I~f ( w, )-f(w’)I ~ ’ ~ for~ ~every ~ = + 1,ri-l + 2, . . . ,ri and i = 1,2, ... ,P k . Hence D 1( f k - f m ( dp < l / k . This shows that limm,k-rm D 5 Ifk -fml d p = 0. Now, we claim that fk, k L lconverges to f hazily. Observe that for any kzl,

120

THEORY OF CHARGES

Hence limk,m p * ( { w E R; If k ( w )-f ( w ) l > integrable.

E})

= 0.

This shows that f is D-

o

The definition of S-integral can be extended to general charge spaces and real functions. See Gould (1965). We link S-integrals and D-integrals in the following theorem. 4.5.8 Theorem. Let ( R ,9, p ) be a charge space and f a bounded real valued function on R. If f is S-integrable, then f is D-integrable and S S f dP = D S f dP.

Proof. The proof of this theorem can be recovered from the proof of the above theorem as follows. For any partition P = {Fl, Fz, . . . , F,} in B and fixed points mi E Fi, i = 1 ,2 , . . ,n, define n

Then, by Theorem 4.5.7 (iii)+ (iv), limPEBu p = a = S f dp. Next, observe that the proof of Theorem 4.5.7 (vii)3 (viii) can be improved to show that if P 2 P k , Q 1P , and k 5 m, then lap- aQ(5 l/k.These two observations

4. INTEGRATION

121

together show that

=

I

lim a p , = a = S f dp.

n-m

As a consequence of Theorem 4.5.7, we obtain the following result. 4.5.9 Corollary. Let 9 be a u-field of subsets of a set R and p a bounded charge on 9. Let f be a bounded measurable function on fl, i.e. f-'(B) E 9 for every Bore1 set B c R.Then f is D-integrable.

Proof. We show that f is the uniform limit of a sequence of simple functions. Let M = SupmEnI f(w)I and d = 2M. For n L 1, let for w in R, fn (0)=

-M

i-1

+7 d, 2

if -M

i-1 + 71 f ( w ) < -M 2

1

+-2"'

f o r i = 1 , 2 , . . . , 2"-1,

=M-- d 2"'

if M

d 2" -

---= f ( w )s M .

It can be checked that fn, n 2 1 converges to f uniformly. Since f is measurable, each fn is a simple function. Hence f is TI-measurable. An application of Theorem 4.5.7completes the proof. 0 Note that i f f is not bounded in the above proof, there is no sequence of simple functions converging to f uniformly.

4.6

L,-SPACES

Let (R, 9, p ) be a charge space. In this section, we introduce some p ) and study function spaces, namely L,-spaces, associated with (R, 9, some of the properties of these spaces. We establish Holder's inequality and Minkowski's inequality to aid the study of these spaces. We also prove Lebesgue dominated convergence theorem. First, we introduce L,-spaces. 4.6.1

Definitions. Let (R, 9, p ) be a charge space. For 1~p
L,(R, 9, p ) = {f ; f is a TI-measurable real valued function on R such that

Ifl"

is D-integrable},

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THEORY OF CHARGES

Lm(R,9, p ) = {f; f is essentially bounded and T1-measurable}, and

Ilfllm

If1

= Essential supremum of = Inf

{k > 0 ; Ip I*({@E R; If(w)I > k}) = 0).

(We use the convention that the infimum over an empty set is co.) If f is a null function, obviously, l f 1 1, = 0 for any 1~p I03. If f and g are such that f = g a.e. [ p ] , f c L P ( f l , 9 , p ) for some 1 s p S c 0 , then g E L,(R, 9, p ) and Il f l , = llgllp We want to show that the nonnegative function II.IIp defined on L,(fl, 9 , p ) for 11p1co is a pseudo-norm on L,(fl, 9,p ) . We need the following inequalities for this purpose. The first of these is Holder’s inequality. 4.6.2 Theorem. Let (R, 9,p ) be a charge space and p and q be two positive numbers satisfying l / p + l / q = l . 1 f f € L p ( f l , 9 , p )and g E L q ( R , 9 , p ) , then fg E Ll(fl, 9, p ) and

llfgll1 5 llfllPllg11q. Proof. Assume, first, that p > 1 and q > 1. The function $(t) =

t P t-+-,

P

9

t >o

has a global minimum at t = 1. Therefore, for every t > 0, $ ( t ) 2 $(1)= l / p + l / q = 1. Let a and b be any two positive numbers and t = (al’q)/(bl’p). Then

This implies that ab s a P / pfbq/q. This inequality is valid even if a = 0 or b = 0. Now, we turn to the proof of the theorem. Iff or g is a null function, then fg is a null function. This can be proved as follows. Suppose f is a null function. Since any T1-measurable function is smooth, g is smooth. So, for a given E > O , there exists k > O such that Ip I*({@ E R; Ig(w)l> k}) I E . Consequently, for any s > 0 , IPI*({@Efln; If(@)g(w)l>S})~ICLI*({@ E n ;I f ( ~ ) l > S l W

+ IPl*({@E 0; Ig(w)l > kl) SO+&

=&.

This shows that fg is a null function. In this case, the theorem is evidently true.

4.

123

INTEGRATION

Since f and g are T1-measurable, fg is TI-measurable. See Corollary 4.4.9(i). By Theorem 4.4.18, fg is D-integrable. It is now obvious that llfgll1 5 ( l / P + ~/q~llfllPll~ll~ = IlfllPllgllq. If p = 1, then q =a.Therefore, lfgl s k l f l a.e. [ p ] for any number k > llgllm. Since fg is TI-measurable, by Theorem 4.4.18, it follows that fg is D-integrable and lFgll1s kllflll for any k >llgllm. Consequently, llfgllls Ilflllllgllm. The case p = 00 and q = 1 can be disposed of in a similar vein. 0

A more general version of the above theorem is the following result.

4.6.3 Corollary. Let (a,9, p ) be a charge space and p , q, r be numbers satisfying 1s p , q, r 5 00 and l / r = l / p + l/q. If f E L p ( R , 9 ,p ) and g E Lq (a,9, P ), then f g E Lr (a,9, CL 1 and llfgllr 5 Ilfllpllgllq* Proof. There are only three possibilities involving 00. Case (i). p = 1,q = 00, r = 1. Case (ii). p = 00, q = 1, r = 1. Case (iii). p = 00, q = 00, r = 00. In Cases (i) and (ii), the result follows from Theorem 4.6.2. For the case (iii), we proceed as follows. For any k > 0 and t > 0 satisfying k > llfl1m and t > llgllm, we have Ir.Ll"({w E n ; I f ( w ) g ( w ) l > k t } ) ~ I l l l * ( { w E n ;

If(w)l>kH

+lPl*(b ER; Ig(4l>tN = 0.

This shows that fg is essentially bounded. Further, llfgllmskt for any k > IIfIIm and t > IIgIIm. Hence IIfgIIm 5 IIfIImIkII.o. Let us look into the case 1< p 1, q/r > 1, E L(p/r)(f49, P ) and IgI' E L(q/r)(fA9, PI. BY Theorem 4.6.2, IfIrIgIrE L ~ ( Q9, P ) and IIlfgl'Ill5 I I l ~ l r I I ~ ~ / r ~ I I lEquivalently, ~lrII~~~r~~

If('

Consequently, llfgllr 5 ~ ~ f ~ ~Since p ~ fg ~ is g TI-measurable, ~ ~ q . fg E Lr(R, 9,p ) .

0 A special case of Holder's inequality is Cauchy-Schwartz inequality.

124

THEORY OF CHARGES

Corollary. Let (a,9,p ) be a charge space and f , g E L2(Q 9, p). Then f g E L l ( f l ,9, p ) and

4.6.4

llfgll1 5 llfl1211g112.

A consequence of Corollary 4.6.3 is the inclusion relations among the L,-spaces. 4.6.5 Corollary. Let (a,9, p ) be a charge space in which p is bounded. Let r and s be any numbers satisfying 15 r 5 s 5 03. Then

Ll(a,~,)~Lr(R,9,p)=,L,(a,9,pCL)LLm(a,~,~CL).

Proof. Since p is bounded, every constant function (which is obviously TImeasurable) is D-integrable. Consequently, If(” is D-integrable whenever f E L,(n, 9, p ) and 15 p < 03. So, the last inclusion relation in the corollary follows. Now, let 1Ir < s ,then f

(a,9, p)

be a charge space and 1‘ p + g E L,(n, 9, p ) and

503. If

f,

Ilf+gll, 5 llfll, fIIgl1,. Proof. The case p = 1 follows from Theorem 4.4.13(viii). If p = 03, it is easy to check that [ I f + gll.. 5 llfll.. + llg1lrn by using an argument similar to the one used in the proof of Case (iii) of Corollary 4.6.3. Assume 1< p COO.Let q be the positive number satisfying l / p + l / q = 1.For any four real numbers al, b l , a2,b2, we have lalbl +u2b215 (/allP+ /az/P)1’P(~bl14 + 1b21q)1/q. This can be seen as follows. Let a ={ol, w z } , 9= P(n)and p ({ol}) = 1= p ({wz)). Let f h = )0 1 , f ( 4 = a2, g ( w d = bl and g ( w ) = b2. Applying Holder’s inequality, we have precisely the above inequality. Note that

lf+glP~ I f l l f + ~ l P - l + I ~ l l f + ~ l P - l 5

( ( f p+I g l p ) l / p ( 2 ( f + g ) q ( p - - l ) ) l / q

5

(IflP

+ l,lp~1~p(21~q>(lf+gop~q.

so, I f + g ) p - ( p / q ) = If+g1521’q(lf(p+ ( g l p ) l / pThus, . we obtain the inequality If+gl” 52p/q(1flp+ Igl”). By Corollary 4.4.9 and Theorem 4.4.18,

4.

125

INTEGRATION

This follows from Holder's inequality. Therefore,

From the above inequality, it follows that (D

[ If+gl" dlul)

'-(l/q)

=Ilf+gllp ~llfllP+llgllP.

0

This completes the proof.

Theorem. Let (fl, 9, p ) be a charge space. Then,for each 15 p 5 00, (Lp(fl,9, p ) , 1) [Ip) is a linear space with a pseudo-norm 11 IIp.

4.6.7

-

Proof. It is now obvious that each Lp(fl,9, p ) is a linear space. Further, if f = 0, then Ilfl , = 0. For any real number c and f in L,(fl, 5 .F, p ) , it is ~ 9,p ) and that Ilcfll, = Ic I l fl1,. The inequality obvious that c f L,(fl, Ilf+gllp 5 l f11, +llgllp for f,g in L,(R, 9, E L ) follows from Theorem 4.6.6.0

Remark. If p is a 0-1 valued charge on a field 9 of subsets of a p ) / - is isometrically isomorphic to the real line R set fl, then Lp(fl,9, for any 15 p 5 CO, where Lp(fl,9,p ) / - is the collection of all equivalence induced by the classes of L,(fl, 9,p ) under the equivalence relation notion of a null function. (See Example 4.4.14.) Consequently, L,(fl, 9,p ) is complete. In general, (Lp(fl,9,p ) , 11 )1, need not be complete. Let fl = {1,2, . .}, 9the finite-cofinite field on fl and p the charge on 9defined by 4.6.8

-

.

p(A) =

1

12"'

if A is finite,

noA

= 2-

1 ".AC

1 2"'

-

if A is cofinite.

126

THEORY OF CHARGES

.

Let A,, = { 1 , 2 , 3 , . . ,n } , n 2 1. We claim that lim D m,n+m

J lIA,,-

This claim is established if we observe that D J IIA, -IA,/ dp = p(A,AA,) which converges to zero as m, n + co.Suppose la,, n L 1 converges to some function f on R hazily. We show that f- 1. For every k 2 1, there exists nk 1 1 such that p*({w E a; IIA,,(W)-~(WI > l/2k}) < 1/2k. Let Bk in 9be ~ ER;l I ~ , ~ ( ~ ) - f ( w )1l/>2 k } ~ B kfor any set such that ~ ( B k ) < l / 2and{w k 2 1. Assume, without loss of generality, that nl < 112 < n3 < * . We now give the properties of the sets Bk, k L 1. (i). Each Bk is a finite set. For, for any infinite set A, p*(A) 2 1. (ii). B k ~ { k + l , k + 2 , .. .}, k 2 l . (iii). I I ~ , , ( w ) - f ( w ) l 5 1/2&,if w&Bk,for k 2 1. (iv). k &Bk,for each k 2 1. Now, let ko in R be fixed. Let E > 0. We show that lf(ko)- 11 < E . This then would imply that f ( k o )= 1. Let N 2 1 be such that 1/2N < E . Let p 2 max{N, ko}. Since B, c { p + 1, p +2, . . .} and p 2 ko, ko & B,. Further, ko E A h c Anko c Anp. Therefore, If(ko)- I A , ~ ( ~=oI f)( ~ k 0 )- 11 5 1/2' 5 1/2N< B . This shows t h a t f s 1. Next, we show that IAn,n 2 1 does not converge to the constant function identically equal to 1 hazily. Let E = i. Then the set {w E 0;[IA,(W) - 11 >b} is a cofinite set and consequently, p ({w E R; IIA,(w)- 11 >b}) 2 1. So, IA., n 2 1 fails to converge to hazily. Thus, we have a Cauchy sequence in L1(R, 9 , p ) not convergent in L1(R, 9, p ) . Hence L l ( R , 9 , p ) is not complete.

4.6.9 Remark. In L,(R, $, p ) , if we introduce the equivalence relation by f - g for f, g in L,(R, 9, p ) if f = g a.e. [ p ] ] ,then the collection of p ) / - of L,(R, 9, p ) equipped with the all equivalence classes L,(R, 9, norm

-

Il[fIIIP = IlfIIP for f in L,(R, 9, p ) is a normed linear space, where [f]is the equivalence p ) containing f. class in L,(R, 9, Next, we aim at proving Lebesgue dominated convergence theorem. For this, we need the following theorem on convergence in L,-spaces.

4.6.10 Theorem. Let (a,9, p ) be a charge space and 1 S p
4.

127

INTEGRATION

(i). f,, n z 1 converges to f hazily. (ii). The charges A, on 9defined by A, (F) = D 5,l f , 1’ dlp 1, F in 9,n z 1 are uniformly absolutely continuous with respect to w, i.e. given E >0, there exists S > 0 such that A, (E)< E for every n 2 1 whenever E E 9 and IP I(E)< 6.

(iii). For each E > 0, there exists a set E, A,(Ez) < E for every n z 1.

E 9 such

that

I(E,) < 00 and

Proof. The proof is carried out in the following steps. 1”. “Only if” part. If h is a nonnegative simple D-integrable function on 0, the following inequality known as Chebychev’s inequality is easy to establish. D IPl({wEa;h(W)>r))s

J h dlPl r

for any r > 0. 2”. In order to show that f,, II 2 1 converges to f hazily, it suffices to show that for any given E > 0 and s 2 > 0, there exist N z 1 and sets A, in 9 for n 2 N such that \pI(A,)< E~ and If , ( w ) -f(w)I < E~ for w in A: whenever n 2N. 3”.Let r and E be two positive numbers satisfying (2r)”’ < s2 and 3 ~ /
and

IP

I*({@E a;Ih, (W f - g, (W >I2 TI)< &IT.

See Lemma 4.4.12. Let B , in 9 be any set such that Ipl(B,)<E/r and {W E a; Ih,(w) -g,(w)l 2 r ) c B,, n 2 1. Let C , = {W E a; h,(w) >r}, n z 1. Then, by lo,lpl(C,) 5 (D 5 h , d(FI)/r for every n z 1. Let A, = B , u C,, n z 1. Then

J

I P I ( A . ) ~ l P I ( B f l ) + I P l ~ c n ~ ~ ~ /hr,+dlPl)/r (D

<E/~+(D

J g, d ~ w ~ + E ) / r

< E / I + ~ E / ~ < E ~ ,

if n rN.

.

128

THEORY OF CHARGES

If w EAE=BznC;, Ifn(w)-f(w)IP= g n ( w ) i h , ( w ) f r 1 2 r which implies that If,(w) -f(w)I i (2r)ljp< E:! for every n 2 1. This shows that f,, n 5 1 converges to f hazily and thus (i) is established. 6”. Since is D-integrable, for E >0, there exists 61 > O such that d l p l < ~ / 2wheneverFE9andIpI(F)<61.Sincelim,+m ~ l f, -flip = D ,5 0, there exists N 2 1 such that D dlp I < ~ / 2 ’for all n >N. Since A l , AZ, . . . ,AN are all absolutely continuous with respect to p , by Theorem 2 F E 9 and 4.4.13(xi), there exists SZ> 0 such that A, (F) < ~ / whenever Ipl(F) < & for n = 1 , 2 , . . . ,N . Let S =min (61,Sz). If F E and~ IpI(F)<S, then for 1i n S N , and ArI(F) < E D ,

Ifl”

Ifl”

If, -fl”

A, (F) = D

\ If, F

-f+fI”

dlp I

< [(&/2”l/P + (&/2”)’/”]”= E ,

for n >N .

This proves (ii). 7”. We now prove (iii).Let E > 0. There exists Eoin 9such that lp ~(EO) < 00 and D jE; dlpl< ~/2’. See Lemma 4.4.15. Further, there exists N 2 1 such that D d l p l < ~ / 2for ~ every n > N . Also, for each n = 1,2, . . . ,N, there exists E, in 9 such that ( pI(E,) < 00 and A,(E‘,) < E . See Lemma 4.4.15. Let E, = EOu El u uEN. Obviously, lp I(EE) < 00. If 15 n s N , then A,(ES)IA,(E;)<E. If n > N , then also,

Ifl”

If, -fl”

-

< [(&/2”)’/”+ (&/2”)’/”1”= E . This completes the proof of “only if” part. 8”. Now, we prove “if” part. First, we show that g = is D-integrable. Let g , = Ifnlp, n L 1. In view of Theorem 4.4.20, it suffices to show that g,, n 1 1 converges to g hazily and

Ifl”

lim D

m,n-co

J

lg, -gml dlpl= 0.

Hazy convergence can be proved as follows, Since each f , is TI-measurable and f,, n L 1 converges to f hazily (by (i)),f is T1-measurable and so, n 2 1 converges to hazily. See Corollary 4.4.9(iii).

Ifl”

lf,lp,

4.

129

INTEGRATION

9". It remains to be shown that the above limit is indeed equal to zero. For this, first, we show that if E E 9 and I(E)< 00, then

Let E > 0. By (ii), there exists 6 > 0 such that A,(F) < ~ / ( + 2 ( p((E))for every n z 1 whenever F E 9 and lp [(F)< 6. Since g,, n 2 1 converges to g hazily, we have m,n+m lim l~l*(b l ~ n ( ~ ) - g , ( ~ ) J ~ ~ / ( ~ + l ~ l ( E ) ) ~ ) = ~ . Consequently, there exist N L 1 and sets En, in 9for n, m r N such that lp I(E,,) < 6 and lg, (0)- gm(w)l< ~ / ( + 2 1~ I(E)) for w in Ei,,, whenever n, m 2 N. Now, if n, m 2 N,

D / lgn-gm/dlPI=D/ E

Ign-grnIdlPI+D E,,nE

J

Ez,nE

Ign-grnIdlPI

This establishes the desired assertion. 10". Next, we show that Iimm,n+w D lg,, -g,l d(pI= 0. Let E >O. By (iii), there exists a set E in 9 such that l(E)< co and A,(E') < E for all n 2 1. Consequently,

sD/EIgn-gmIdIPI+E+E l . < 00, for all n, m 2 1. Taking limits as n, m -f CO, we obtain, by 9" as ( ~ I(E) that limm,,+wD (g,, - g, 1 d ( pI 5 2.5. Since E > 0 is arbitrary, the above limit is indeed equal to zero. Hence g is D-integrable. = 0. Let A. on 9be defined by 11". Finally, we show that limn-tml f, - f [ l , Ao(F)= D jFIflp dip[, F in 9.By Theorem 4.4.13(xi) and Lemma 4.4.15, (ii) and (iii) hold for the sequence Ao, AI, AZ, . . . also.

130

THEORY OF CHARGES

Let E >O. By (iii), there exists E, in such that Ipl(E,) 0 such that (An(F))””< E for every n 2 0 whenever F E 9 and lp I(F)< 6. Since f n , n 2 1 converges to f hazily, there exist sets A, in 9such that limx+m[yl(A,) = 0 and \ f , ( w ) - f ( ~ ) I< r for every w in A‘, and n 2 1. So, there exists N 2 1 such that IpI(An)<6 if n 2 N . Now, let rz 2 N . Then

+(D

JA“IflP dliLI)l/p

<E+E+~[J~~(E,-A,)]~/~+E+E

< E + E + r[lp I(EE)I1”+ E

+E <5

~ .

Hence limn,oo D If, - f l p dlpl= 0. This completes the proof of the theorem. 4.6.11 Remark. If p is bounded, condition (iii) is not required in Theorem 4.6.10. We need the following notion of hazy convergence for nets and the attendant result in the proof of Lebesgue dominated convergence theorem. 4.6.12 Definition. Let (a, 3,p ) be a charge space and f a , a E D be a net of real valued functions on 0. fa, a EDis said to converge to f hazily if for every E >0,

4.

131

INTEGRATION

The following result says that the limit function f is T1-measurable if each f, is T1-measurable.

4.6.13 Proposition. Let (Q, 9,p ) be a charge space and f a , a E D a net of T1-measurable functions on Q converging to a function f hazily. Then f is T1-measurable. Proof. In view of Theorem 4.4.7, it suffices to show that f is T2-measurable. Let E > 0. There exists a. in D and a set A in 9 such that 1p I(A) < ~ / 2 and If,,(w) -f ( w ) l < ~ / for 3 all w in A‘. Since f,, is T2-measurable, there exists a partition {Fo,F1,F2, . . . , F,} of Q in 9such that Ip ~(FO) < ~ / and 2 If,,(w) -fa0(w’)I< ~ / for 2 all w , w ’ in Fi for i = 1,2, . . . , n. Let Eo = A u Fo, and Ei = Fi nA‘, i = 1,2, . . . , n. {Eo,El, E2, . . . , En}is obviously a partition & .w , w ‘ E E ~ for any i = of Q in 9.Further, I p 1 ( E o ) < ~ / 2 + ~ / 2 = If 1 , 2 , . . . , n, then If(d-f(w’)l~If(w)-fa,(~)l+lfao(~)-f~,(w’)l

+Ifa,(W’)-f(4

< &/3-k &/3-k &/3= E . 0

This completes the proof.

Now, we are ready to prove Lebesgue dominated convergence theorem.

4.6.14 Theorem Let (Q, 9, p ) be a charge space and g E L,(Q, 9,p ) for some p 2 1. Let f,, a E D be a net of T1-measurable functions on Q such that Ifal 5 lgl a.e. [ p ] .Let f be a real valued function on Q. Then the following statements are equivalent. (a). f a , a E D converges to f hazily. (b). ~ E L ~9, (Q p ),and lim,.D Ilfa -flip = 0. If p = 1, the following statements are equivalent. (a’). f a , a E D converges to f hazily. (b‘). f E L1(R, 9,p ) and lim,,D D 1, ( f a -f ) dlpl= 0 uniformZy over F in

9. (c’). f

E L1(fl, 9, p)

and lim,.,,

D1 , If a -f l dlp I = 0 uniformly over F in

9. (d’). f ELI(Q,g, p ) and lim,.D D

Ifa - f l

d b l = 0.

Proof. We prove the first part. By Theorem 4.4.18, each f a E L,(R, 9,p ) . Assume that the net f a , a E D is really a sequence f n , n 2 1. Suppose (a) holds. We verify (i), (ii) and (iii) of Theorem 4.6.10. (i) holds by virtue of the validity of (a). We show that (ii) holds. Let E >O. By Theorem 4.4.13(xi), there exists 8 > O such that D jF lglp dlp I < E whenever FE9 and Ip [(F)< 8. Since Ifnl c Igl a.e. [ p ] for every n 1 1,it follows that D jFIf n 1’ dlp I < E whenever F E 9and lp I(F) < 8. Thus (ii) holds. Next, we show that (iii) of Theorem 4.6.10 holds. By Lemma

132

THEORY OF CHARGES

4.4.15,thereexistsasetFEi n 9 s u c h t h a t IpI(F,) O and pa > a for every (Y in D such that I l f p , -f[Ip > E . Then fpQ, a E D , being a subnet of fa, a E D , also converges to f hazily. So, again, there exists a sequence & < pm2< * * such that fpQ , n 2 1 converges to f hazily. But, by what we have proved for sequencGs, limn+mI l f p Qn -flip = 0. This is a contradiction. Hence [If, -fll, = 0. Thus for nets, (a)J(b) holds. Similarly, ( b ) j(a) can be established for nets too. We come to the second part. The equivalence of (a’) and (d’) follows from the first part. The implications (d’)3 (c’) (b’) are clear. We prove a E D. Then the uniform (b’)+ (d’). Let A,(F) = D 5, ( f , - f ) dip I, F E 9, convergence of A,, a E D to zero implies that IA, l(R), (Y E D converges to 0 zero, because ]A, l(R>= SUPFESIA, (F)-A, (Fc)l.

+

We end this section with a result on the denseness of D-integrable simple p ) for 1 5 p < a. functions in L, (R, 9, 4.6.15 Theorem. Let ( R , 9 , p ) be a charge space. Let Sim(R,9, p ) be the space of all D-integrable simple functions on R. Then Sim(R, 9, p ) is dense in L, (R, 9,p ) for every 1 5 p < CO.

Proof. Let 1 s p < a be fixed and f~ L,(R, C ,F , p ) . For a given E >O, by Lemma 4.4.15, there exists a set A in 9 such that IpI(A)
<0+EP.

From this, it follows that Ilf-I~fll,< E . Now, we look at IAf.Let f n , n 2 1 be a sequence of simple functions converging to IAf hazily. By Lemma 4.4.17, we can assume that Iffl I 5 2IA(fl for every n 2 1. By Lemma 4.4.16, Iffl/’ is D-integrable for every n 2 1. By Lebesgue dominated convergence theorem, limn+mllfn - I ~ f l l = , 0. Consequently, there exists N ? 1 such that llfN -IAfllp < E . From this, it follows

4.

133

INTEGRATION

that

0

4.7 ba(fk,9) AS A DUAL SPACE In this section, we introduce a Banach space whose dual is the space of on the field 9 of subsets of a set R. We also all bounded charges ba(R, 9) consider some extensions of this result.

4.7.1 Definition. Let 9 be a field of subsets of a set 0. A real valued function f on R is said to be 9-continuous if given E >0, there exists a partition {F1, FZ,. . . , F,} of R in 9 such that 1 f ( w ) -f (w’)I < E for all w , W ’ in Fi and for every i = 1 , 2 , . . . , n. Let %‘(a,9)denote the collection of all 9-continuous functions on 0. It is obvious that every 9-continuous function is bounded. Further, the space %‘(a, is a linear space. All simple functions are available in % ( R , 9 ) . On U ( 0 , %‘), we introduce a norm by 11fll= Sup {I f(w)l; w E R} for f in %(a, It is obvious that 11 11 is indeed a norm on %(a, 9)If.A E9 and A # 0, then IIIAll = 1.

a a.

4.7.2 Proposition. Let 9 b e a field of subsets of a set R. Then the following statements are true. (i). (%(a, 9), 11 * 11) is a Banach space. (ii). The collection of all simple functions is a dense subset of %(a, 9). (iii). f is $-continuous if and only iff is the uniform limit of a sequence of simple functions on 0. n s l be a Cauchy sequence in %(R,S). Let f ( o ) = Then fn, n 2 1 converges to f uniformly over R. We show that f is 9-continuous. Let E >O. There exists N 2 1 such that Sup {I f N ( 0 ) -f (o)l;w E R}< ~ / 3For . fN, there is a partition {Fl, F2, . . . ,Fk} for all o,w ’ in Fi and for every of R in $ such that I f N ( W ) - f N ( o ’ ) I < E / 3 i = 1,2, . . . , k . Let i E {1,2, . . . ,k} and w , W ’ E Fi. Then

Proof. (i). Let

fn,

f,(w), w

E R.

If(d-f(w’>I 5 If(4 -f”

+lfN(W)

-fdw’)I

+IfN(W’)

-f(w’>I

< &/3+ &/3+&I3= E. This shows that f is 9-continuous. It is obvious that limn+mllfn -f l l = 0. II.II) is a Banach space. Hence (%‘(R,

134

THEORY OF CHARGES

(ii). Let f be $-continuous. For n rl, there is a partition {F,I, Fn2, . . . , Fnk,} of R in 9 such that for every i E {1,2, . . . , k,}, I f ( w ) - f ( w ' ) l < l / n for all w , w' in Fni.For each n 2 1 and i = 1,2, . . . , k,, choose and fix wni in Fni.Let

If(@)

-f,(w)I = We claim that f,, n 2 1 converges to f uniformly. If w E F,i, If(w)-f(wni)< l l / n for all n 2 1 and i = 1,2, . . . ,k,. Consequently, Ilf-f,ll< l / n for all n 2 1. Hence Ilf-f,ll = 0. This shows that the class of all simple functions on R is a dense subset of %(a,8. (iii). This is now obvious. 0

We now give a characterization of $-continuous functions based on D-integrability.

Theorem. Let 9be a field of subsets of a set R. Then f E %'(a,fl if and only i f f is D-integrable with respect to every bounded charge A on $.

4.7.3

Proof. Let f~ %(R, 9). Note that if A is a bounded charge on 9, then f is Tz-measurable with respect to A and hence is D-integrable. See Theorem 4.5.7. Conversely, suppose f is D-integrable with respect to every bounded Suppose f is not $-continuous. There exists E > O such that charge on 9. there exists 1Ii In satisfying given any partition {F1,F2, . . . ,F,} of R in 9, O(f,Fi) = Sup{lf(w)-f(w')l; w , O'E Fi}> E . For each partition P = {F1,F2, . . . ,F,} of R in 9, let A(P) = U{Fi; 1 si I n , O(f, Fi)> E } . Let B denote the collection of all finite partitions of R in 9. Then {A(P); P E 9 ) is a filter base in 9. To see this, let P1, Pz E 8 and P any partition in B finer than both P1 and Pz. Suppose for some F in P, O ( f ,F) > E . Then F is contained in some G1in PI and in some GZin P2. Consequently, O ( f ,GI)> E and O ( f ,Gz)> E . Thus F c G1nG2 and from this, it follows that A(P) c A(P1)nA(P2). Further, note that A(P) # 0 for every P in 8.Thus we have proved that {A(P); P E P } is a filter base in $. Hence there is a maximal Define A on 9by filter 8 in 9containing {A(P); P E 8}. A(E)=l, ifEE'iY, =0, ifEg'iYandEE9. A is a 0-1 valued charge on 9.

We claim that f is not D-integrable with respect to A. Suppose f is D-integrable with respect to A. Then f = c a.e. [A] for some constant c. See Example 4.4.14. Then A*({w E R; if(w)-cl > s / 2 } ) = 0. Consequently, there exists B in 9 such that {w E R; I f ( w ) - c I > ~ / 2 c} B and A(B)=O. Now, we look at the partition P={B,B"} in B. Then

4.

135

INTEGRATION

B ' c ( w ~ 0 ;I f ( w ) - c l 5 & / 2 } . For any w , w' in B', I f ( w ) - f ( w ' ) l I If(w)-cl+)f(w')-cI S E / ~ + E / ~ = E . Therefore, O ( f ,B')IE. Hence A(P) = B E 8. By the definition of A, A (B) = 1.This contradiction proves the 0 desired assertion. Now, we characterize the continuous linear functionals on (%(a, 9), II-II). 4.7.4 Theorem. Let 9 b e a field of subsets of a set 0.Let T b e a continuous linear functional on %(a, Then there exists a unique bounded charge p on 9 s u c h that

e.

for every f in %(a, 9).Further, llTll= Sup {IT(f)l; llflls1}=Ipl(a). Conversely, for any given bounded charge A on 9, the functional T' on %'(a, 9) defined by T ' ( f )= D J f dA, f in %(a, 9) is a continuous linear functional on %'(a, 9-with ) IlT'll= IA /(a). If T is a nonnegative linear functional on %?(a, 9), i.e. T (f ) 2 0 i f f 2 0 , then p is a positive charge. I AE %?(a, 9)and S O , define p (A)= T(IA).It is obvious Proof. For A in 9, that p is a charge on 9.Also, IpLA)I= IT(IA)I 511TllllrAl1511Tll

for every A in 9. This shows that p is a bounded charge on 9.Now, we 9), T ( f )= D J f d p . Iff ciIAi is a simple claim that for any f in %?(a, function in %(a, then

=xi"=,

a,

T ( f )=

i=l

ciT(IAi)=

f

i=l

c i p ( A i )= D

J f dp.

For any f in %(a, 9), by Theorem 4.7.2, there exists a sequence f n , n 5 1 of simple functions in %(a, 9) converging to f uniformly. It is obvious that f,,, n 2 1 converges to f hazily. Further, since p is bounded,

Thus, f n , n 2 1 is a determining sequence for f with respect to p. Consequently,

D

J'

f dp

= lim n+m

D

as T is continuous on %(a, 9).The claim is thus established.

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THEORY OF CHARGES

Now, if fE%‘(R,.F) and llfilsl,then ~ T ( f ) ~ = ~ D ~ f d p ~ ~ D ~ Ipl(R). See Theorem 4.4.13 (iii). Hence ~ ~ T \ ~ I ~ Since ~ ~ Ipl(R) ( R ) =. Sup Ip (Ai)/,where the supremum is taken over all finite partitions {Al, A2, . . . ,A,} of R in 9, for any given E >0, there exists a partition (FI,F2, . . . ,F,,,} of R in 9such that m

Since E > 0 is arbitrary, we have Ip I(R) IIlTll. This shows that llTll= Ip [(a). The rest of the theorem is obvious. 0

4.7.5 Corollary. The dual of %‘(a,9)= %‘*(a, 9) = ba(R, F). 4.7.6 Corollary. Let X be a compact Hausdorff totally disconnected space, 9 the field of all clopen subsets of X, 93 the Bore1 u-field on X, %(X)the space of all real continuous functions on X and ca(X, 93) the space of all bounded regular measures on 93. (%(X) is a Banach space under supremum norm and ca(X, 93) is a Banach space under total variation norm.) Then the following statements are true. (9. %(X, 9) = The space of all .%continuous real functions on X = %(X).

(ii). (Riest Representation Theorem.) If T is a continuous linear functional on %(X), there exists a unique bounded regular measure p on 93 such that

T(f)=D

If

dp

for f in %(X) having the property that llTll= lpl(X). (iii). The dual of %(X)= %*(X)= ca(X, 93).

Proof. (i). Suppose f is a continuous real valued function on X. For E > O and for each x in X, there exists a clopen set C, containing x such that

4.

137

INTEGRATION

I f ( y ) - f ( x ) l < ~ / for 2 all y in C,. {C,; x EX} is an open cover for X. Since X is compact, there exists a finite subcover {C,,, C,,, . . . ,CXn}of X. For each 11i%n and for every x , y in CXi, we have I f ( x ) - f ( y ) l I I f ( ~ ) - f ( ~ i ) l + I f ( ~ i ) - f ( y ) ( < ~ / 2 + ~ / 2 = ~ . Let Di=Cxl, D2= C,, - C,,, . . . ,D, = CXn-(GIu C,, u . * u CXn-,). Then {Dl,D*,. . . ,D,} is a partition of X in 9and for this partition, we still have I f ( x ) -f(y)I < E for all x , y in Di and for all i = 1,2, . . . ,n. Hence f is $-continuous. . Conversely, if f is $-continuous, it follows easily that ~ E % ( X )This proves (i). (ii). Let T be a continuous linear functional on %(X).By Theorem 4.7.5, there exists a bounded charge C; on 9 such that T ( f )= D J f dC; for every f in %(X). C; can be extended as a measure on the Baire a-field Boof X. can be extended as a regular measure p on B. See Theorem 3.5.5. This completes the proof of (ii). (iii). This is obvious now. 0

-

4.7.7 Remark If 9 is a field of subsets of a set R, then %(a, 9) can be realized as %(X)for some compact Hausdorff totally disconnected space X.

Now, we obtain some natural subspaces of ba(Cl, 9) as dual spaces when a-field.

$ is a

We consider the following set-up. Let R be a set, 8 a a-field of subsets (ii) I. C, E $ if C c A, C E %?I of R and 9 a proper cr-ideal in 8, i.e. (i) 4 c ? and A E 4 , (iii) R @ 4 and (iv) Unal A,, E 9 if A,, n 2 1 is a sequence in 9. A real valued function f on R is said to be measurable if f-'(B) E 8 for every Bore1 set B c R. A measurable function f on R is said to be essentially bounded if there exists k > O such that {w E R; \ f ( w ) \> k } E 9 . If f is an essentially bounded measurable function on R, define

Ilfllm

= Inf

{ k ;k > 0 and

{w E R; If(w)I > k} E 9).

Obviously, 0 Illfllm < a. Let Lm(RZ, a, 9)denote the collection of all essentially bounded measurable functions on R. If f E Lm(Q%, 9), then A={w =

u

nzl

If(w)l>IIfllmI @En;

If(w>l>llfllm-tl/n}

€9.

Further, we show that A has the following properties. (i). SUP{lf(w)t; 0 E A'} = IFll==. ; E A'- B} = llfllm for any B in 4. (ii). Sup { l f ( w ) / w Obviously, Sup { I f ( w ) l ;w E A'} 5 llfllm. If Sup {If(o)(; w E A'} < llfllm, then {w'ER; If(w')l>Sup{If(w)l; w E A ' } } ~ A and hence {w'ER;If(w')I> Sup {If(w)l; w E A'}} E 9.But this contradicts the definition of llflloo. (ii) can be proved analogously.

138

THEORY OF CHARGES

-

4.7.8 Proposition. The function 11 Jlmdefined on L,(R, M, 9)above has the following properties. (i). llcfllm = IcI llfllm for any real number c and f in L,(R, a, 9 ) . 6).Ilf + gllm 5 llfllco + llgllm for allf, g in Lm(R, M, 9). Proof. (i). This is obvious. (ii). Note that {w €0;l f < ~ ~ + ~ ( ~ ) l > I l f l l m + + l ~ I I ~ ~ C{W

€0;If(~)l>llfil~I

u l w En; Id~I>llSll~}E.a.

Consequently, Ilf + gllm 5 llfllm + llgllm-

0

4.7.9 Proposition. (L,(R, M, 9 ) ,1)- llm) is a h e a r space and pseudo-norm under which L,(R, M,9) is complete.

11.1)m

is a

Proof. It is clear the L m ( R , M,9) is a linear space and that Il*llm is a pseudo-norm on Lm(R, a,9).We show that Lm(R, %,9)is complete. Let fn, n 2 1 be a Cauchy sequence in Lm(R,Vl, 9). For every n, m 2 1, let Anrn={w Ea;I f n ( ~ ) - f r n ( ~ ) l > l l f n - - f r n I l m } . Then for any B in 9, SUP{Ifn ( w )-frn(w>I; w E A;rn--B}

=

llfn -frnll,*

LetA=Un,,Urn,,Anrn. T h e n A E 9 and lim Sup(~fn(w)-frn(w)~;o €A'}=

rn,n-m

lim

llfn-frnllm=O.

rn,n-m

Let f ( w ) = limn,m f n ( w ) for w in A'. Then f n , n L 1converges to f uniformly on A". For w in A, define f ( w ) = 0. We claim that l f n -film, n L 1converges to zero.

llfn -fIL

= IKfn - f ) l A c + Il(fn -f)lAcllm

(fn

+ Il(fn

-f)lAllm

0 This completes the proof.

5 SUP {Ifn(w)-f(w)I;

which converges to zero as n + 00.

-fV*lIm w E A?+

In the present context, we define a null function as follows. A real valued measurable function f on R is said to be a null function if {w E R; If(o)I> k } E 9 for every k > 0. This is equivalent to the condition that )lfllrn = 0. The space of all null functions is a linear subspace of Lm(R, M, 9).We introduce an equivalence relation on Lm(R, M, 9)by f-g if f - g is a denote the collection of all equivalence null function. Let 2?m(R,8,9) classes of Lm(R, M, 9). The pseudo-norm 11. llm defines unambiguously a norm on Z,,(R, a, 9) which is again denoted by 11 llm. Now, it is apparent that Ym(R,a,9)is a Banach space. We work out its dual.

-

6

4.

139

INTEGRATION

4.7.10 Theorem. Let T be a continuous linear functional on (Lm(R,%, 9), 11 llm). Then there exists a unique bounded charge p on % with the following properties. (i) T ( f ) = D J f d p f o r e u e r y f i n Lm(R,%,9). (ii). llTll= IpI(W. (iii). p (A) = 0 i f A E 4;.

Proof. For A in 8,let @(A)= T(IA). p is obviously a charge on a. Note that T(f) = 0 whenever f is a null function. If A E 9,then IAis a null function and so, p (A)= 0. This proves (iii). The boundedness of p follows from the inequalities IpL(A)I= IT(IA)l

5

~

~

~

~

~

~

~

~

A

~

for any A in a. If f is a simple function, it is obvious that T(f)= D jf dp. Let f be any function in Lm(R, %, 9) with llfllm>O. We show that T(f)= D Jfdp. Let B = {w E R; If(w)I 5 Ilfllm}. Note that B“E 4. Let d = 211fllm. For each n z 1, define (similar to the construction given in the proof of Corollary 4.5.9)fn as follows. For w in R,

for i = 1 , 2 , . . . , 2 ” -1,

It is easy to check that f,,,n z 1 converges to f uniformly on B. We claim that f,,,n z 1 is a determining sequence for f with respect to p. It is obvioils that each fn is a simple function. For any E > 0, Ip

I({@

E

a;Ifn

(@)-f(@)l>

Elf =

l({w

E

B; Ifn (@> -ff@)l>

+ IPKb E B‘;

Ifn(4

I))

-f(d > &I)

= 0,

if n is sufficiently large. This assertion follows from lp [(B‘) = 0 and fn, n 2 1 converges to f uniformly on B. This shows that fn, n 2 1 converges to f

~

m

5

~

\

140

THEORY OF CHARGES

hazily. Also,

= 0.

Hence f n , n L 1 is a determining sequence for f. Since IIfn - fllm IIl(fn - f)I~ll~ + Il(fn - f ) I ~ c l l ~ , it follows that limn+m\Ifn - film = 0. Since T is a continuous linear functional on Lm(fl, %, $1,

T ( f )= lim T ( f n = ) lim D n+m

n-m

I

fn

d p =D

I

f dp.

Next, we show that ~ ~ T ~ ~ = ~For p ~any ( f lf )in. Lm(R,%,9),ITl= ID d p I I D 1 dlp I s Ip I(fl)llfllm. Hence, it follows that llTll5 Ip I(fl). Just as in the case of Theorem 4.7.4, we can show that Ipl(fl)crllTll. Thus 0 llTll= )pl(fl)holds true. This completes the proof.

If

If1

For the following corollary, let ba(R, %, 9) stand for the space of all bounded charges on % vanishing on 9. We equip ba(fl, %, 9)with the total variation norm.

4.7.11 Corollary. The dual of Ym(fl,%, 9 ) is isometrically isomorphic to ba(fl, %, 9).

CHAPTER 5

Nonatomic Charges

Classification of charges is an obvious pursuit one embarks on for a good understanding of charges. We have already come across 0-1 valued charges in Chapter 2. In this chapter, we examine what could be an antithesis of the notion of a 0-1 valued charge. Section 5.1 develops the relevant classification of charges. The Sobczyk-Hammer decomposition theorem is presented in Section 5.2. We prove some existence theorems for nonatomic charges in Section 5.3. Finally, in Section 5.4, we consider the plentitude of nonatomic charges.

5.1 BASIC CONCEPTS The notion corresponding to nonatomicity of measures on cr-fields can be introduced for charges in three different ways. We show that these three ways are actually distinct for charges.

5.1.1 Definition. Let 9 be a field of subsets of a set R. A set F in 9 is said to be a p-atom if the following conditions are satisfied. (i). p( F ) # 0. (ii). If E E 9 and E c F, then either p (E)= 0 or p (F- E) = 0.

If F is a p-atom, then the restriction of p to F n9 is a 0-p (F) valued charge on the field F n9of F. However, if p restricted to the field F n9 for an F in 9 is two valued, F need not be a p-atom. Also, it is not difficult to check that an F in 9 is a p-atom if and only if F is a Ipl-atom. For, if F is a p-atom, E E 9, E c F and p (E)= 0, then Ip I(E) = 0. Note that if F E 9, F is an atom of 9 and p (F)# 0, then F is a p-atom. However, a p-atom need not be an atom of 9. Non-existence of p-atoms is one way of defining a class of charges. More formally, we give the following definition. 5.1.2 Definition. Let 9 be a field of subsets of a set R and p a charge on 9. p is said to be nonatomic on 9 if there are no p-atoms in 9. Equivalently, if F E 9 and p (F) # 0, then there exists E in 9 such that EcF,p(E)#Oandp(F-E)#0.

142

THEORY OF CHARGES

In view of the remarks made after Definition 5.1.1, it follows that p is nonatomic if and only if Ip I is nonatomic. If p is a positive bounded charge on 9, then p is nonatomic on 9, if for every F in 9 with p (F)> 0, there exists E in 9such that E c F and 0 < p (E)< p (F).Now, we prove a simple property of nonatomic charges.

5.1.3 Proposition. Let 9 be a field of subsets of a set R and p a positive bounded nonatomic charge on 9. Then given F in 9 with p(F)>O and E > 0 , there exists E in 9 such that E c F and 0 < p (E)< E .

Proof. Since p is nonatomic, there exists El in 9 such that El c F and 0

Ez 3 1 zp (En-l)I(1/2")p (F). If N L 1 is such that (1/2N)p(F)< E , then E = EN serves the purpose. 0

-

The following definition is inspired by a certain property of nonatomic measures on a-fields. 5.1.4 Definition. Let 9 be a field of subsets of a set R and p a charge on .5F. p is said to be strongly continuous on 9, if for every E >0, there exists a partition {F1,Fz, . . . ,F,} of R in 9 such that Ip1(Fi)<&for every i. Obviously, if a charge p on 9 is strongly continuous on 9, then it is bounded. One might conjecture that a charge p on 9 is strongly continuous on 9 if and only if for every E >0, there exists a partition (F1, Fz, . . . ,F,} of R in S such that ) p(Fi)l< E for i = 1 ,2 , . . . , n. But this conjecture is not true. Any non-zero charge p on 9with p (R) = 0 satisfies the later property. The following definition is inspired by yet another property of nonatomic measures on u-fields.

5.1.5 Definition. Let 9 be a field of subsets of a set R and p a charge on 9. p is said to be strongly nonatomic on 9, if for every F in 9 and 0 IC 5 lp I(F), there exists E in 9such that E c F and Ip I(E)= c. The following theorem gives the inter-relations between these concepts.

5.1.6 Theorem. Let p be a positive bounded charge on a field 9 of subsets of a set R. Then each of the following conditions implies the succeeding condition. (i). p is strongly nonatomic on 9. is strongly continuous on 9. (ii). (iii). p is nonatomic on 9.

5.

143

NONATOMIC CHARGES

If, in addition, p is a measure and 9 i s a u-field, then these conditions are all equivalent. Proof. The implications (i)J(ii)+(iii) are immediate. If p is a measure and 9 is a a-field, we show that (iii)+(i) using what is known as the “principle of exhaustion”. Let F E 9 and 0 Ic Ip (F) be given. Let %‘ = {C E 9; C c F and p ( C )Ic}. On V,we introduce the following partial order. For C1, CZin V,CIS Cz if p (Cl - Cz)= 0. We show that every chain in %’ has an upper bound in V. Let { C , ; /3 E D} be a chain in %’.Let r = Sup & ( C , ) ; /3 E D}. We can find a sequence C,, IC,, I * * such that r = p (Con).Let C = Un=l C,,. Obviously, C E V and p ( C )= r. It is easy to verify that C is an upper bound of the given chain. By Zorn’s lemma, V has a maximal element, E say, i.e. if C E %‘ and E 5 C , then p (C - E) = 0. We claim that p (E) = c. Suppose p (E)< c. Then p (F- E) = p (F)- p (E)2 c - p (E)> 0. Since p is nonatomic, by Proposition 5.1.3, there exists a set Eo in 9 such that E c c F - E and O 0. This contradicts the maximality of E. Hence p (E)= c. 0

5.1.7 Remarks. (i). A nonatomic positive bounded charge on a field 9 of subsets of a set R need not be strongly continuous. The following is a relevant example. Let R = [0,1] and 9 the field on R generated by the collection of all intervals of the form (a, 61 c [$,f). Let p be the restriction of the Lebesgue measure to 9. Then p is nonatomic on 9but not strongly For E =$, there is no decomposition of R in 9 which continuous on 9. satisfies the required properties. (ii). A strongly continuous positive bounded charge on a field 9of subsets of a set R need not be strongly nonatomic. The following is an example substantiating this statement. Let R = [0, 1).Let 9 be the field of all sets each of which is a finite disjoint union of intervals of the type [a, 6) with rational end points and 01 a Ib I1. Let p be the Lebesgue measure restricted to 9. Then p is strongly continuous on 9 .but not strongly nonatomic on 9. (iii). If p is a strongly continuous positive bounded charge on a u-field 9 of subsets of a set R, then p is strongly nonatomic on 9. In other words, (ii)+(i) in Theorem 5.1.6 is valid if 9 is a u-field on R. See Theorem 11.4.5 for a proof. (iv). If p is a bounded charge on 9,Theorem 5.1.6 still remains valid. If p is a charge on a field 9 without necessarily being bounded, then (i) (iii) in Theorem 5.1.6. (v). If 9 is a u-field on R, (iii)+(ii) in Theorem 5.1.6 is not true even though (i)e(ii). Let R=[O, 11, 9 = B o r e l u-field on R, A =Lebesgue A (B) = 0). Let T be any 0-1 valued charge measure on 9 and 4 = {BE 9;

+

144

THEORY OF CHARGES

on 9 such that T(B)= 0 for every B in 4. Let p = A + 2 ~ Then . p is nonatomic on 9but not strongly nonatomic on 9. Now, we examine the problem of characterizing strong continuity of a charge p in terms of the positive and negative variations, p + and p - , of p, as strong continuity plays a dominant role in the decomposition theorem to be proved in the next section.

5.1.8 Proposition. Let 9 be a field of subsets of a set R. (i). A bounded charge p on 9 is strongly continuous i f and only if p + and p - are strongly continuous. (ii). I f p1 and p2 are bounded strongly continuous charges on 9,then p 1 + p2 is strongly continuous. Proof. (i) follows from the facts that p + s I p I , p - s I ~ l . 1and I p I = p + + p - - . (ii) follows from the fact that l p +pzI ~ 5 Ip11+ 1 ~ 2 1 . The following proposition is useful in establishing the uniqueness part of the decomposition theorem of Section 5.2. 5.1.9 Proposition. Let 9 be a field of subsets of a set R and p,, n 2 1 a sequence of 0-1 valued charges on 9.Let a,, n 2 1 be a sequence of real anp, is numbers such that Cnzl lanlCOO.I f the bounded charge p =CnZl non-zero, then p is not strongly continuous on 9. Proof. Assume, without loss of generality, that lull >O. If p is strongly continuous on 9, then 1pl is also strongly continuous on 9. Now, since l a l l p l s lpl =Cnzlla,Ipn, p1 must be strongly continuous. But no twovalued charge is strongly continuous. 0 5.2 SOBCZYK-HAMMER DECOMPOSITION THEOREM

In this section, we prove the Sobczyk-Hammer decomposition theorem for charges. According to this theorem, we can write every charge p as a sum of two charges, one of which is strongly continuous, the other a countable sum of two-valued charges. We need some preliminary results. 5.2.1 Definition. Let 9 be a field of subsets of a set R. A sequence p,, n 2 1 of 0-1 valued charges on 9 is said to be finitely disjoint if for every n 2 1, there exists a partition {FI,Fz, . . . ,F,} of R in 9 such that pi(Fi)= 1 for every i = 1,2, . . . ,n. This notion essentially means that any finite subcollection of {p,, n 2 1) have disjoint supports. This notion is equivalent to the sequence pn,n 2 1 being distinct. This is stated in the following proposition.

5.

NONATOMIC CHARGES

145

5.2.2 Proposition. Let 9 be a field of subsets of a set R. A sequence p,, n L 1of 0- 1valued charges on Sisfinitely disjoint if and only if the sequence p,, n 2 1 is distinct, i.e. no two charges in the sequence are the same.

Proof. “Only if” part is obvious. “If” part. This can be proved by induction. Since p1 and p 2 are distinct, we can find A, in 9 such that p1(Al)#p2(A2). Assume, without loss of generality, that pl(A1)= 1. Then {Al, A;} is the desired partition for p1 and p 2 . Suppose, for pl,p 2 , . . . , p,, there is a partition {F1, F2, . . . , F,} of R in 9 such that F ~ ( F= ~1 ) for i = 1 ,2 , . . . ,n. Since pi and p,+1 are distinct, we can find Ei in 9 such that pi(Ei)= 1 and P,+~(E:)= 1 for every i = 1,2, . . . ,n. Let Bntl = E: and Bi = Bztl n Fi, i = 1,2, . . ,n. Then {Bl,B2,.. .,B,,Bntl} is a partition of ft in 9 and p i ( B t ) = l for i = 1 , 2,..., n + l .

nL

5.2.3 Remark. (i). If p,, n L 1is a sequence of distinct 0-1 valued charges on a field 9of subsets of a set R, it is natural to ask whether the sequence is infinitely disjoint, i.e. there exists a partition {F1,F2, . . .} of R in 9such that p , ( F n ) = 1 for every n 2 1. But this is not the case as the following example shows. Let R = {1,2 ,3 ,. . .} and 9= B(O), the class of all subsets of R. Let p1 be any 0-1 valued charge on B(R) such that p l( A) = 0 for every finite subset of R. See Example 2.1.3(4). For n 2 2 , let p, on 9 be defined by @,(A) = 1, if n E A,

=0, ifngA. This sequence p,, n z 1 of distinct charges is not infinitely disjoint. (ii). If 9is a c-field on R and p,, n L 1 is a distinct sequence of 0-1 valued then pn,n L 1 is infinitely disjoint. measures on 9, The following definition is useful to express the notion of strong continuity

of a charge in a form convenient for the development of the subsequent results.

5.2.4 Definition. Let 9 be a field of subsets of a set R and p a charge Let P={FI, F2,. . . ,F,} be a partition of R in 9.Then the number on 9. p p is defined by p p = max p ( F i ) . lcisn

Let B be the collection of all finite partitions of R in 9. A positive bounded charge p on 9is strongly continuous if and only if InfpEpp p= 0. This assertion is obvious from the definition of strong continuity of p. The following two lemmas lead to the decomposition theorem.

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THEORY OF CHARGES

5.2.5 Lemma. Let 9 be a field of subsets of a set R and p a positive bounded charge on 9 which is not strongly continuous. Let a = InfpEBpp. Then there exists a set F in 9 s u c h that (i). a 5 p (F)< 2a, and (ii). a Ip (Fi)for some Fi in any partition {FI, Fz, . . . ,F,} of F in 9.

Proof. Since p is not strongly continuous, a > 0. Choose any O < E
=0, i f p ( A n F ) < a .

Then A is a charge on 9. Proof. Let A and B be two disjoint sets in 9. Case (i). p ( ( A u B ) n F ) < a . Then p ( A n F ) < a and p ( B n F ) < a . Consequently, A ( A u B )= 0 = 0+0 = A (A)+ A (B). Case (ii). p ( ( Au B ) nF) L a. Then p ( A nF ) + p ( B nF) L a. Since p (F) = p ( A n F) + p ( B n F) + p ( F - ( A uB ) n F) < 2a, p(F- ( Au B ) n F) < a. Looking at the partition { A nF, B nF, F- ( Au B ) nF} of F and in view of property (ii) of Lemma 5.2.5, either p (A nF) Ia or p ( B nF) ? a . Note that both these inequalities cannot hold simultaneously. For, if they hold, then p (F) ? p ( A nF) + p ( B nF) I2a contradicting property (i) of Lemma 5.2.5. Consequently, A ( A u B ) = a = A ( A ) + A ( B ) . This proves the lemma. 0 Finally, we prove the main theorem of this section. 5.2.7 Sobczyk-Hammer Decomposition Theorem. Let 9 be a field of subsets of a set R and p a positive bounded charge on S. Then there exists a sequence pn,n 2 0 of distinct positive bounded charges on S a n d a sequence a,, n 2 1 of nonnegative numbers with the following properties. (i). po is strongly continuous on .!F. (ii). p, is a 0-1 valued charge on 9for every n L 1.

5.

NONATOMIC CHARGES

147

(iii). Cnrl a, COO. (iv). F = p0+Cnzl anpn. Further, the decomposition (iu)is unique. u,*p,* be another Proof. First, we establish uniqueness. Let p = pg +Inzl decomposition, where pg is a strongly continuous charge on 9,p,*, n z 1 is a sequence of 0-1 valued charges on 9 and a,*, n L 1 is a sequence of nonnegative numbers satisfying CnZla: < 00. Assume, without loss of generality, that pn’s are distinct, an’spositive, pz’s distinct and az’s positive. (Either sum Cnzl a,p, and Inzl a:p,* or both could be a finite sum. The following argument carries through in these cases also.) We show that p ; = po and anpa,n L 1 is a permutation of u,*p,*,n L 1. Observe that

*

c

Po - p o =

~nllfl-

fl2l

C a:&,*. fl2l

By Proposition 5.1.8, pg - p o is strongly continuous. By Proposition 5.1.9, it follows that pg = po and CnZla,p, =Inzl a,*p,*.Next, we claim that {anpn; n 2 1)= {a,*p,*; n L 1). Suppose this is not true. If {anp,; n 1 1) is not a subset of {a ,*p: ; n L l),there is an element a l p 1, say, of {a+, ;n L 1) which is not a member of { a , * p : ; n L 1). Choose N z 1 such that Cn2N+1a,* < al. Since p 1, p p . . . , p $ are distinct (why?), we can find Fin 9such that p 1(F)= 1 and p (F)= 0 for i = 1,2, . . . ,N. See Proposition 5.2.2. Consequently,

T,

ail

C

,251

z,

T

anpn(F)=C a:p:(F)= ns1

C

nzN+1

a,*p,*(F)
This contradiction shows that {a,p, ; n 2 1)c {a,*fi,* ; n L 1). By a similar argument, we can show that {a,*p,*;n 2 l)c{a,p,; n L 1). Thus we have proved that {a,*p,*; n L 1) ={a,p,; n L 1). Since the charges in each set are distinct, it follows that u,pn, n L 1 is a permutation of a:p:, n L 1. This establishes uniqueness. Now, we prove the main part of the theorem. If p is strongly continuous, then the conclusion of the theorem is trivially true. So, assume that p is not strongly continuous. Let InfPEppp= al. Then a l > 0. Let p i be the 0-al valued charge on 9 as defined in Lemma 5.2.6. Note that p i s p . Let A 1 = p - p i. Or, equivalently, p = p i + A 1. If A is strongly continuous, we stop here and we have the desired decomposition. If A 1 is not strongly continuous, using the argument given above, we can write A l = p ; + A2, where p i is a 0-a2 valued charge with a2>0, where a2 = InfPEp( p Continuing this way, we either stop at a finite number of steps reaching the desired decomposition or obtain a sequence p:, n L 1 of charges such that each p : is 0-a, valued with a, >O. In this case, CnZla, <00 since p is bounded. Let po= p -Inzl p:. We claim that po is strongly continuous.

148

THEORY OF CHARGES

Observe that

for all N. Since aN -* 0 as N -* 00, we have that InfPEp(po)p = 0, i.e. po is strongly continuous. Writing each p = a+,, where each p, is a 0-1 valued charge, we obtain the desired decomposition. 0

5.2.8 Remark. The above decomposition theorem is also valid for any bounded charge p on 9.We can work out decompositions for p + and p separately and from these we can obtain a decomposition of p in the form p0+Cflz1a,p,, where p o is strongly continuous, each p, is a 0-1 valued charge and Cnzl la,l
c Ffl,

nzl

where (i) po is strongly continuous on 9, and (ii) p, is O-a, valued with a, > O for every n L 1. (a, could be equal to 00.) (The sum Cnzl pn could be a finite sum.) Since p is unbounded, p is not strongly continuous. But for any x >0, the charge p restricted to [0, x ) n9 is strongly continuous. It follows that p,([O, x ) ) = 0 for every n L 1 and p ([0, x ) ) = po([O,x ) ) = x . This shows that po is an unbounded charge on 9. Consequently, it cannot be strongly continuous. Hence p does not admit a decomposition along the lines of Theorem 5.2.7. The above example worked because every strongly continuous charge is necessarily bounded. By relaxing the definition of strong continuity of charges, we obtain a Sobczyk-Hammer like decomposition theorem for positive unbounded charges p. For A in 9,let p / A be the charge on A n 9 defined by (p/A)(B) = p(B) for B in 9and B c A.

5.2.10 Definition. Let 9 be a field of subsets of a set fl. A positive charge p on 9 is said to be strongly continuous on Fif p / A is strongly continuous on A n 9 f o r every A in 9 with p ( A ) < a . 5.2.11 Theorem. Let 9 be a field of subsets of a set fl and p a positive unbounded charge on 9. Then there exists a strongly continuous charge po

5.

on 9 a n d a family

NONATOMIC CHARGES

149

a E r}of two valued charges on 9 s u c h that

c Pa

p=po+

asT

and {pa; a E I?} is finitely disjoint, i.e. for any distinct al,a2,. . .,a,, in r, there exists a partition {A,,, A,,, , . .,A=,,}of R in 9 such that @*,(Ai) = pai(R)for i = 1,2, . . . ,n and n 2 1. (Here r could be uncountable!) Proof. Let %' ={A E 9; p (A)< 00). %' is a ring on R. For each A in %', by Theorem 5.2.7, we can write p/A=pOA+

c

piA,

izl

where p o A is a strongly continuous charge on A n and p ; A , i 2 1 is a sequence of two valued charges on A n 9 which are finitely disjoint. pi^ could be a finite sum.) Because of the uniqueness of the decomposition in Theorem 5.2.7, the charges poA,A EV are consistent in the following sense: if A, B E %' and B c A, then p o ~ / B= poB.Define po on 9 as follows.

(cizl

POW= POA(A), if A E%', = a,

if A&%' and A€%.

a charge on 9 and is, obviously, strongly continuous in the sense of Definition 5.2.10. For i 2 1 and A in %',let fiiA(F)= piA(FnA) for F in 9. Each &A is a two-valued charge on 9. Let UAt~{fiiA; i 2 1}= { p a;a E r}.Now, it is not difficult to verify that po is

5.2.12 Remark. It is possible to show that the above decomposition is essentially unique. As a corollary of Theorem 5.2.7, we can obtain the following decomposition theorem of Measure theory.

5.2.13 Corollary. Let 9 be a a-field of subsets of a set R and p a positive bounded measure on 9. Then we can write N

R = U A , , or nzO

UA,, n=O

for some N 2 0 with the following properties. (i). An's are pairwise disjoint. (ii). A,, is a p-atom for every n # 0. (iii). The restriction of p to the a-field A. n9is a nonatomic measure.

150

THEORY OF CHARGES

Proof. By Theorem 5.2.7, we can write

where (i) p o is strongly continuous on 9, (ii) p,,, n L 1 is a sequence of distinct 0-1 valued charges on 9, and (iii) a,, > 0 for every n 2 1 with Cnrl a,,
5.3 EXISTENCE OF NONATOMIC CHARGES In this section, we examine the conditions under which there exists a .F of subsets of a set SZ. The non-zero nonatomic charge on a given fieldC following definition is instrumental in providing a solution. Definition. Let 9 be a field of subsets of a set SZ. A collection of non-empty sets {Fil,iz ,...,ik; i l , i 2 , . . . , i k is any finite sequence of 0’s and l’s, k 2 1)in is said to be a tree in 9if the following conditions are satisfied. (i). FouFI = SZ, FonFl = 0. GI. Fil.iz .....i k - 1 . 0 ~ Fii.il.....ik-l,l =Fi1.i2.....ik-, andFi,,i, ,....ik-l,onFil,i2 ,...,i k - l . l = 0 f o r a l l i i , i z , . . . , i k - i ~ { O , 1)andk 2 2 .

5.3.1

The following theorem provides a set of equivalent conditions for the existence problem.

5.3.2 Theorem. Let 9 be a field of subsets of a set SZ. The following statements are equivalent. (i). There is a non-zero positive bounded nonatomic charge on 9. (ii). $contains a tree. (iii). There is a non-zero positive bounded strongly continuous charge on 9.

5.

NONATOMIC CHARGES

151

Proof. (i)+(ii). Let p be a non-zero positive bounded nonatomic charge on 9.Since p(R)>O, we can find Fo, F1 in 9 such that FouF1=R, FOnF1= 0 , 0 < p (Fo)< p (a) and 0 < p (F1)< p (R). Applying this technique to FOand FI separately, we obtain Foo,FOI,FIO,F11. Continuing this way, we obtain a tree in 9. (ii)+(iii). Let {Fil.i2 ....,ik; i l , iz, . . . ,ik E (0, 1) and k 2 1) be a tree in 9. Let 90be the smallest field on R containing this tree. In fact, gois precisely the collection of all finite disjoint unions of sets in the tree. Define ~ o ( ..... F it)~ =~1/2k , ~foril, ~ iz,. . . , i k in(0, 1)andk 2 l.pOcanbeextendedin the obvious fashion to Soas a charge p l . Note that p l is a strongly continuous positive bounded charge on go.Let p2 be any positive charge on 9 which is an extension of p1. See Corollary 3.3.4. It is obvious that p2 is strongly continuous on 9. (iii)J(i). This is part of Theorem 5.1.6. n

The above theorem provides an interesting implication for a-fields.

5.3.3 Corollary. Let 9be an infinite a-field of subsets of a set R. Then there exists a non-zero strongly continuous positive charge on 9. Proof. In every infinite a-field, one can find a sequence A,, n 2 1of pairwise disjoint non-empty sets whose union is R. This can be proved as follows. Let B be any non-empty set in 9whose complement, B", is also non-empty. Then either B n9 or B ' n 9 is infinite. If B n9 is infinite, we can find non-empty sets B1, BZ in 9 such that B1 u Bz = B and B1nBz = 0. Then either B l n 9 or B 2 n 9 is infinite. Proceeding this way, we obtain a sequence of pairwise disjoint non-empty sets. From this, we can obtain A,,, n 2 1 with the stated properties. Write the set N = (1,2, , . .} = N1 u N2, where N1 and Nz are disjoint infinite sets. Let FO= UiEN1 Ai and F1 = UiENZ Ai. Splitting N1 into two disjoint infinite subsets as above, we obtain Fooand Fol. Applying the same technique to Nz, we obtain Flo and F11. Proceeding this way, we obtain a tree in g.Theorem 5.3.2, now, completes 0 the proof.

Theorem 5.3.2 also provides useful information on superatomic fields. Keeping in mind the definitions of an atom, atomic field and nonatomic field in Definitions 1.4.9, we define superatomic fields as follows.

5.3.4 Definition. Let 9 be a field of subsets of a set R. 9 is said to be superatomic if every sub-field of 9is atomic. 5.3.5 Remarks. (i). If R = { 1 , 2 , R, then 9is a superatomic field.

. . .) and 9 is the finite-cofinite field on

(ii). Let a be any ordinal and R=[O,a] be equipped with the order topology. This is the topology on R which has the collection of all subsets

152

THEORY OF CHARGES

C of R of the form ( a , 6 ) or [O,b)or ( a , a ]for O s a s b ICY as a base. Let 9be the field of all clopen subsets of R. Then 9is superatomic. See Pierce (1970). (iii). Let .F1 and SZbe superatomic fields on Rl and respectively. Let 9109~ be the smallest field on Rl X RZ containing {AX B; A E 9 1 and B E 95).Then S1092 is a superatomic field. (iv). If 9 is a field on a set R, then 9 is superatomic if and only if the Stone space X of 9 is scattered, i.e. no non-empty subset of X is perfect. See Sikorski (1969) especially the statement on page 35 under D. The following theorem gives equivalent versions of superatomicity and describes all the bounded charges explicitly on superatomic fields. 5.3.6 Theorem. Let 9 be a field of subsets of a set R. The following statements are equivalent. (i). 9 is superatomic. (ii). $does not contain a tree. (iii). There is no non-zero nonatomic positive bounded charge on 9. (iv). There is no non-zero strongly continuous positive charge on 9. (v). Every positive boundedcharge p on 9 h a s the following representation

where ( a ) ai 2 0 for every i and valued charge on 9.

Cizl ai <m,

and ( 6 ) each pi is a 0-1

Proof. The implications (ii)+ (iii)+ (iv)+ (v) follow from Theorem 5.3.2 and Theorem 5.2.8. (v)+(i). Suppose (v) holds and (i) is not true. We show that 9 contains a tree. Since 9 is not superatomic, there is a subfield Poof 9 which is not which does atomic. This implies that there exists a non-empty set A in 90 Then we can find A. and A1 in 90 such that not contain any atom of go. A. u A1= A, A. n A1= 0, A. # 0 and A1# 0. Repeating this procedure on A. and A1,we obtain Aoo,Aol c A. and Alo,All c A1having properties similar to the above sets. Continuing this way, we obtain a collection {Ail.iz,...,it; il, i2, . . . ,ik E (0, 1) and k 2 1)of non-empty sets in Powith the properties (a) Ai1,iZ.....ik-1.0UAil.iz.....ie-1.1 =Ail.iz,....i k - 1 and (b) Ail,iz,.... i k - 1 , o n Ai1,iz.....i k - 1 . 1 = 0 for all i l , iz, . . . ,ik-l in {0,1} and k 2 2. From this, it is not difficult to obtain a tree in 9. Consequently, by Theorem 5.3.2, there exists a non-zero

5.

NONATOMIC CHARGES

153

strongly continuous positive charge on 9. Such a charge can never be decomposed in the way condition (v) stipulates. This contradiction proves the desired implication. (i) j(ii). If 9 contains a tree, then the subfield generated by the tree is nonatomic and hence 9cannot be superatomic. This contradiction proves the desired implication. 0 We now proceed to obtain some topological conditions for the existence problem of nonatomic charges. We need some preliminary results for this purpose. Proposition. Let 2 be a u-field of subsets of a set a,9 a field on generating 2 and p a positive bounded measure on a. Then p is strongly continuous on 2 if and only if p is strongly continuous on 9. 5.3.7

Proof. “If” part is trivial. “Only if” part. Assume that p is non-zero. Let E >O. Let m be a natural number such that l / m < E . Since p is strongly continuous on a, we can find a partition {F1, F2,. . . , F,} of fl in ‘tisuch that

for every i. For each 1Ii In, by Theorem 3.5.3, we can find Gi in 9such that

Since G i c Fi u (FiAGi),we have

for every i. Further,

s

n

n

i=l

i=l

C p ( F i - G i ) s C p(FiAGi)
Defining D1=G1, D i = G i - U j l \ G j for i = 2 , 3 , . . . ,n and Dn+l= n-Ur=l Gi, we observe that {D1, D 2 , . . . ,Dn+l}is a partition of s1 in 9 0 satisfying p (Di)< E for every i. This completes the proof. The following result provides a simple necessary and sufficient condition for nonatomicity of regular measures on the Bore1 u-field of a compact Hausdorff space.

154

THEORY OF CHARGES

Lemma. Let X be a compact Hausdorff space, W its Bore1 u-field and W O its Baire a-field. Let p be a positive bounded regular measure on 9.Then the following statements are equivalent. (i). p is nonatomic on 3. (ii). p ( { x } ) = 0 for every x in X. (iii). p is nonatomic on Wo. 5.3.8

Proof. (i)J(ii). This is obvious. (ii)3 (iii). Let B in Wo be a p-atom. Since p is regular, p (B) = Sup { p (C); C c B, C E $3330and C is a compact Gs subset of X}. Since p (B) >0, there exists a compact Gs set C contained in B such that p(C) >O. Let x E C. Since p is regular, 0 = p ( { x } )= Inf (II.(V); x E V, V an open F, set c X} and therefore, we can find an open F, set V, containing x such that p (V,) < p (C).{V, ; x E C} is an open cover for C. There is a finite sub-cover {V,,, V,,, . . . ,V,,,} of C. Since B is a p-atom, C is a p-atom. Since p (V, nC) 5 p (V,) < p (C), it follows that p (V, n C) = 0. Consequently, p (C) = p ((U~=I VXi)n C) = 0. This contradiction shows that there are no p-atoms in Wo. Hence p is nonatomic on Wo. (iii)J(i). Since p is nonatomic on Wo, p is strongly continuous on Wo. See Theorem 5.1.6. Hence p is strongly continuous on the bigger a-field W. So, p is nonatomic on W. O The following theorem gives some more equivalent versions for the existence of non-zero nonatomic charges, mainly topological in nature. 5.3.9 Theorem. Let 9 be a field of subsets of a set Q and X its Stone space. The following statements are equivalent. (i). There is a non-zero nonatomic positive bounded charge on $. (ii). There exists a countable nonatomic subfield 90of 9. (iii). X contains a perfect set. (iv). 9 contains an ideal 4; such that the quotient Boolean algebra 91.9 is nonatomic.

Proof. (i)+(ii). By Theorem 5.3.2, 9 contains a tree. The smallest field Soon Q containing a tree is a countable nonatomic subfield of 9. (Note that a tree is obviously a countable collection of sets.) See Corollary 1.1.14. (ii) (iii). Let so be a countable nonatomic subfield of 9.Without loss of generality, assume that gois generated by a tree. Let Y be the Stone space of so. See Theorem 1.4.10. We note that Y is perfect. In fact, Y is homeomorphic to the Cantor set {0,1}"". This follows from the fact that and goare isomorphic. For, the field V of all clopen subsets of (0, l}Ko since V is generated by the tree {{il}X {i2}X * x {in}x (0, 1)x * * ; i l , iz, * ,in ~ { 0 , 1 and } n 2 1) and gois generated by a tree, V and 9,, are isomorphic. It is obvious that (0, 1)"" has no isolated points, i.e. it is

+

-

-

5.

NONATOMIC CHARGES

155

perfect. Since the inclusion map i from goto 9defined by i(A) = A, A E $0 is a one-to-one homomorphism, there exists a continuous function f from X onto Y . See Theorem 1.4.11. Now, we claim that there exists a minimal closed subset P of X such that f ( P ) = Y. The collection 8 = {E c X; E is closed and f (E)= Y } is non-empty and is partially ordered by set inclusion, i.e. for El, EZin 8, say El IE2 if El c EZ.Let {E, ;a E D }be a chain in 8. We claim that E, E 8. Let y E Y. For each a in D, there exists x, in E, such that f (x,) = y. Since X is compact, there exists a subset of x,, a E D converging to some element x in X. Further, x p E E, whenever p Ia , since {E,; a! E D} is a chain. Consequently, since E, is closed, x E E, for every cy in D. Thus x E n,=DE, and f ( x ) = y . Hence E, is a lower bound of the chain {E, ;a E D}. So, we have proved that every chain in 8 has a lower bound. By Zorn’s lemma, there exists a minimal closed set P c X such that f ( P )=Y .

n,,D

naED

We also claim that P is perfect. Suppose not. Let x be an isolated point of P . Since P - { x } is compact, f ( P - { x } ) = Y - { f ( x ) } is compact. Consequently, f (x) is an isolated point of Y . This implies that Y is not perfect. This is a contradiction. Hence P is perfect. (iii)+(iv). Let P be a given perfect subset of X. Let V be the collection of all clopen subsets of X. Let 9’ = {CE V;P nC = 0).9’is clearly nonempty and is an ideal in %. We claim that the quotient Boolean algebra V/9’is nonatomic. Let [A] be a non-zero element in V/9’. Then A n P # 0. Further, A n P contains at least two points x, y E X , because P is perfect. Since X is compact and totally disconnected, there exists C, D in V such that X E C C A , ~ E D and ~ A C n D = 0 . Note that O<[C]<[A] and O<[D]<[A]. Consequently, %I$’has no atoms. Since 9 and V are isomorphic, (iv) follows. (iv)+(i). Since $19 is nonatomic, 919 is not superatomic. By Theorem 5.3.6, there is a non-zero nonatomic positive bounded charge p on 919. Using the quotient homomorphism from 9 to 919,the charge p can be lifted as a charge @ on 9. @ is obviously nonatomic. This completes the proof. Finally, we close this section with a result on the existence of nonatomic measures on the Borel u-field of a compact Hausdorff totally disconnected space.

5.3.10 Corollary. Let X be a compact Hausdorff totally disconnected space and W its Borel u-field. Then there exists a non-zero nonatomic positive bounded regular measure on W if and only if X contains a perfect set. Proof. Suppose p is a non-zero nonatomic positive bounded regular measure on W.Then p is a nonatomic measure on the Baire cr-field Wo of

156

THEORY OF CHARGES

X. See Lemma 5.3.8. Consequently, p is strongly continuous on Wo. See Theorem 5.1.6. Note that the field %' of all clopen subsets of X is a generator See Section 1.3. By Proposition 5.3.7, p is strongly continuous on of a0. %'.By Theorem 5.3.9, X contains a perfect set. Conversely, let X contain a perfect set. Let %' be the field of all clopen subsets of X and Wo its Baire a-field. By Theorem 5.3.9, there exists a non-zero strongly continuous positive bounded charge p on %'.Every charge on %' is a measure. See Example 2.3.5(3). Since Wo is generated by %, there is a measure C; on Wo which is an extension of p. See Section 1.3 and Theorem 3.5.2. By Proposition 5.3.7, fi is a strongly continuous positive measure on Wo. Let A be the regular measure on W which is an extension of I;.. See Theorem 3.5.5. By Lemma 5.3.8, A is nonatomic. This 0 completes the proof.

5.4

DENSENESS

Let 9 be a field of subsets of a set R. Let A be the collection of all A is equipped with a topology as follows. A net probability charges on 9. pa, (Y E D in A is said to converge to a p in A if pu,(F)= p (F) for Let A 1be the collection of all nonatomic probability charges every F in 9. on 9 and A Zthe collection of all strongly continuous probability charges Obviously, A 2c A1c A.In this section, we examine the conditions on 9. under which A 2is dense in A.We need a preliminary result. 5.4.1 Proposition. Let 9 be a field of subsets of a set a. Let X be the If X is perfect, then for any given non-empty set F in 9, Stone space of 9. there exists a strongly continuousprobability charge p on S s u c h thatp (F)= 1.

Proof. The perfectness of X is equivalent to the fact that 9 is nonatomic. In the field F n9 on F, one can easily construct a tree. By Theorem 5.3.2, there exists a strongly continuous probability charge A on F n9. Define p on 9by p (E) = A (E nF), E E 9. p is the desired charge. The following is the main result of this section. 5.4.2 Theorem. Let 9 be a field of subsets of a set R and X its Stone space. Then A2 is dense in A if and only if X is perfect.

Proof. "If" part. Let p EA.We construct a net of strongly continuous probability charges converging to p. By Theorem 5.2.7, we can write

5.

NONATOMIC CHARGES

157

where (i) po is a strongly continuous positive charge on 9, (ii) ai L O for every i and po(R)+Iizl ai = 1, and (iii) p i is a 0-1 valued charge on 9 for every i L 1. Let 9i= {FE 9;p i (F)= l},i L 1.For every F in gi,choose and fix a strongly continuous probability charge pi,^ on 9such that pi,F(F)= 1. This can be done in view of Proposition 5.4.1. Consider the product set 91 X P zx with the following partial order. For (F1,FZ,. . .) and (El, Ez,. . .) in 9 1 X 9 2 x * , say (F1,F2,. . .) L (El, E2,. . .) if Fi c Ei for x sz x * . . is a directed set. For every i. Under this partial order L, S1 FZ,. . .) in S1 x s zx * * , let p(F1,~2 ,...) = p 0 + 1 + ~aipi,Fi.It is easy every (F1, to check that ~ ( F ~,...), FE Atz. ~ We claim that the net p(FI,F2,...), (F1, Fz, . . .) E S1 x 95 x * * converges to p in the topology of A. Let E in 9 be fixed. Let NI = {i L 1; E E 9i} = {il, i2, . . .} and {1,2,3, . . .}-{il, i2, . . .} = { j l , j z , : . .}. Since 95 is a maximal filter, E“Eq k for every k L 1. Define E: for each n L 1 by

--

-

-

-

ifn = i l , i z , . . . ,

E:=E, =E‘,

if

~t =jl,j2,.

...

-

Let (F1,FZ,. . .) in 9 1 x 9 z x * * be such that (F1,FZ,. . .)r(ET,E;, . . .). This implies that Fi c E for i = il, iz, . . . and Fi E” for i = j l , j z , . . . . Con= po(E)+C,,, aik= CLW. Hence the net sequently, ~(F~,F~,...)(E) ~ ( F ~,...I. F(E), ~ (FI,Fz, . . .) E X 9 2 X * * converges to p (E).This completes the proof of the “if” part of the theorem. “Only if” part. Since the perfectness of X is equivalent to the fact that 9 is nonatomic, it suffices to show that 9 has no atoms. Suppose F in 9 is an atom of 9.Take the probability charge p on 9 such that p(F) = 1. By the hypothesis, there exists a net pot a! E D in A2 converging to p in the topology of A. In particular, lirnmSD p, (F)= p (F)= 1. But p, (F) = 0 for every a! in D. This contradiction proves the result. 0 3

The following corollaries follow guite easily from the above theorem. 5.4.3 Corollary. Let 9be a field of subsets of a set R whose Stone space X is perfect. Then given any 0-1 valued charge p on 9, there exists a net pa, cu E D of strongly continuous probability charges on 9converging to p in the topology of A.

Corollary. Let 9be a field of subsets of a set R. Let X be the Stone space of 9. Then the following statements are equivalent. (i). 9is nonatomic. (ii). X is perfect. (iii). Azis dense in A. (iv) A lis dense in A.

5.4.4

158

THEORY OF CHARGES

Finally, we state a result in topological measure theory. Let X be a compact Hausdorff space and 93 its Bore1 u-field. Let A* be the collection of all regular probability measures on 93. The weak* topology on A* is described as follows. A net p,, a E D in A* converges to a p in A* if limaED5 f dp, = f d p for every real valued continuous function f on X. If, in addition, X is totally disconnected, a net pa, a E D in A* converges to a p in A*in the weak* topology of A * if and only if limaGDp, (C) = p (C) for every clopen set C c X . This follows from the fact that (f:X+R:, f= C J ~ ,for some cl, c2,. . . ,cn real, ~ 1 ~ , 2 , ...,C, clopen sets cx and n 2 1) is norm dense in the space of all real continuous functions on X equipped with supremum norm. See Section 1.3. Let A?be the collection of all regular nonatomic probability measures on 3.

xr=l

5.4.5 Corollary. Let X be a compact Hausdorff totally disconnected space and A" and AT be as defined above. Then A? is dense in A* in the weak" topology of A" if and only if X is perfect.

CHAPTER 6

Absolute Continuity

In this chapter, we formally introduce the notions of absolute continuity and singularity for charges. In Section 6.1, we study various properties of absolute continuity and singularity in the framework of charges and establish the connection with the existing notions of absolute continuity and singularity in Measure theory. In Section 6.2, we obtain Lebesgue Decomposition theorem for charges using Riesz Decomposition theorem in Vector lattices. Finally, in Section 6.3, we prove Radon-Nikodym theorem.

6.1 ABSOLUTE CONTINUITY AND SINGULARITY The following notion of absolute continuity is the main one we study extensively in this section.

6.1.1 Definition. Let p and v be two charges defined on a field 9 of subsets of a set SZ. v is said to be absolutely continuous with respect to p i f given E >0, there exists S > 0 such that Iv(E)I < E whenever E E 9 and Ip /(E)< S. If v is absolutely continuous with respect to p , we use the notation v << p.

6.1.2 Remarks. There are two other notions one could introduce related to absolute continuity. (i). v is said to be weakly absolutely continuous with respect to p if v(E) = 0 whenever E E 9 and Ipl(E) = 0. In this case, we use the notation vw< 0, there exists S > 0 such that Iv(E)I < E whenever E E 9 and lp (E)I< S. In this case, we use the notation V S K p. In the following, we clarify the inter-relations between these three types of absolute continuity.

6.1.3. Remarks. Let p and v be two charges on a field 9 of subsets of a set 0. (i). vw<

160

THEORY OF CHARGES

(iii). u < < p implies uw<<w. But the converse is not true. Let R = {l,2 , 3 , . . .}, 9=S(R),the class of all subsets of R and p on 9 be defined by

p(A)=

c

1

neA

for A in 9. Let u be any 0-1 valued charge on 9 such that u(F) = 0 for any finite subset F of R. It is obvious that U W K p. On the other hand, u is not absolutely continuous with respect to p. For E = $, there is no S > 0 such that u(F) < E whenever F E 9 and p (F) < 6. For any given S > 0, one can always find a cofinite set F such that p (F) <8. (iv). If p is a positive charge, then u << p if and only if v s << p. (v). If us<
6.1.4 Proposition. Let p and u be two charges defined on a field 9 of subsets of a set R. Then the following statements are equivalent. (i). u << p. (ii). u+<

O. Since u << p, there exists S > 0 such that Iu(F)I < ~ / whenever 2 F E 9and Ip I(F) <S. So, if F E 9and l@l(F)<S, then v+(F)=Sup{v(B); B c F , B E % ] I E / ~ < E . Hence v+<<@. Similarly, one can show that v-<< p . (ii)+(iii). If (ii) holds, clearly u+<< lpl and V - K IpI. Hence IuI = u++u-<< IF

I.

(iii) 3 (i). This is obvious. For the last part, observe that if u << p+, then u << p + + A for any positive charge A on 9.In particular, u << p + + p - = Ip 1. 0 Now, some comments are in order on the above proposition.

6.1.5 Remarks. (i). If u < < p , neither u < < p + nor v < < p - need hold. As an example, let R={1,2}, 9 = S ( R ) , p({l})=& p({2})=-$, ~ ( { l } ) ~ = $ a nu({2})=1. d Note that p+({l})= 4, ~ ~ ( ( 2=)0,) ~ ~ ( ( 1=)0,) pL-({2})= 2 and Ipl= u. Therefore, u << p. But neither u << p + nor u (< p - is valid.

6.

ABSOLUTE CONTINUITY

161

(ii). Proposition 6.1.4 still remains valid if absolute continuity is replaced by weak absolute continuity in the statement. (iii). Proposition 6.1.4 is not valid if absolute continuity is replaced by strong absolute continuity. Some simple examples based on those in (i) can be provided.

As has been pointed out earlier, absolute continuity and weak absolute continuity are not equivalent in general. However, for bounded measures on a-fields, these two notions are equivalent.

6.1.6 Theorem. Let 9 be a a-field of subsets of a set R and p and v measures on 9 s u c h that v is bounded. Then vw<

O such that for every n 2 1, there is a set Fn in 5F such that ]pI(Fn)< 1/2” but Iv](Fn)2 E . Then the ,ret F = lim sup,,m F, has the property that lp I(F)= 0 and IvI(F)2 E . To prove this, we proceed as follows.

the other hand, since Ivl is bounded,

n u Fk)=!L21vl(gnFk)

IVl(F)=lvl( n z l

kzn

r l i m sup lv/(Fn)2

~

.

n+m

Thus we have IpI(F)=O and IvI(F)zE. But this is a contradiction to the assumption that v w p.~ This completes the proof. 0

6.1.7 Remark. In the above theorem, neither the assumption of boundedness of v nor the assumption that the measures are defined on a a-field can be dropped for its validity. (i). We treat the boundedness part of the above theorem. Let R = [0,1], 9= Bore1 u-field on R and p the Lebesgue measure on 9. Define Y on

162

THEORY OF CHARGES

9by v(A)=O,

ifAE9andp(A)=O,

= m , if A E 9 a n d p ( A ) > O . It is easy to check that v is a measure on 9 and that vw<
.FA 1

if A E 9 and A is finite, 1

=1- C ..AC

.(A)=

2"'

1 1neA

=2-

ifAE9andA'isfinite. if A E 9 and A is finite,

2"' 1

C -

noAC2"'

if A E 9 and A' is finite.

Note that p and v are charges on 9. Every charge on 9 is a measure. Obviously, vw< O such that v(E) < E whenever E E and~ p(E)<S, then we can find a set A in 9 such that A' is finite and p (A) < S. For any such set A, v(A) > 1. This contradiction shows that v is not absolutely continuous with respect to p. Now, we examine the notion of absolute continuity for measures on fields vis-a-vis with that on a-fields. The following theorem ties up the notion of absolute continuity for charges and the known notion of absolute continuity for measures on a-fields.

6.1.8 Theorem. Let 9 be a field of subsets of a set fl and 2l the a-field on R generated by 9.Let p and v be two positive bounded measures on 8. T h e n v < < p o n 9 i f a n d o n l y i f v < < p o8n . Proof. If v << p on 8 , then it is obvious that v << p on 9. Now, we assume Let E > 0. There exists S > 0 such that v(E) < ~ / whenever 2 that v << p on 9, E E 9 and p (E)/S. Now, let F E 8 and p(F) < 6/2. We show that v(F) < E . By Theorem 3.5.3, there exists a set E in 9 such that p (FAE)+ v(FAE)< min { ~ / 26/2}. , Then lp (F)- p (E)I Ip (FAE)< S/2. Consequently, p (E)< p (F)+S/2 < S/2 + S/2 = 6. Therefore, v(E) < ~ / 2 .On the other hand, v(FAE)<&/2 from which it follows that Iv(F)-v(E)l<~/2. So, v(F)< v(E) + ~ / <2~ / 2 ~+ / =2E . This completes the proof of the theorem. 0

6.

163

ABSOLUTE CONTINUITY

6.1.9 Remark. The above theorem is valid for any two bounded measures and v.

p

We now study s-boundedness of charges in the light of absolute continuity. See Definition 2.1.4.

6.1.10 Theorem. Let p and v be two charges on a field 9 of subsets of a set 0. Then the following statements are true. (i). v is s-bounded if and only if 1vI is s-bounded. (ii). If v << p and p is s-bounded, then Y is s-bounded. (iii). If Y << p , p is s-bounded and v is a real charge, then v is bounded. (iv). If v << p , p is bounded and v is a real charge, then v is bounded. Proof. (i). Suppose v is s-bounded and lv( is not s-bounded. Then there exist a sequence A,,, n 2 1 of pairwise disjoint sets in 9 and E > O such that IvI(A,) > E for every n 2 1. Write IvI(A,,)= v+(A,,)+ v-(A,) for every n 2 1. Then there exists a sequence n l < n z < ' . such that v + ( A , , ) > ~ / 2 for every i 1 1 or there exists a sequence kl< k z < * such that .-(Aki)> ~ / for 2 every i 2 1. Assume that the former holds. Since v+(A,,) > ~ / 2 , there exists Bi in 9 such that Bi CAniand v(Bi)>&/2for every i L 1. Bi, i 2 1 is a sequence of pairwise disjoint sets in 9and limi+a v(Bi)f 0. This contradiction proves that Iv 1 is s-bounded. The converse is trivial. (ii). If v < < p , then v < < 11.1.1. By (i), lpl is s-bounded. Therefore, v is sbounded. (iii). Every s-bounded real charge is bounded. See Corollary 2.1.7. (iv). This follows from (iii) and the fact that every bounded charge is s-bounded. 0

-

Now, we study the countable additivity property of charges in the presence of absolute continuity.

6.1.11 Theorem. Let p and v be two charges defined on a field 9 of subsets of a set 0. If v << p, v is a real charge and ,u a bounded measure, then v is a measure.

n,,,

Proof. Let A,,, n 2 1 be a decreasing sequence of sets in 9 with A,, = 0 .It suffices to show that limn+mv(A,) = 0. See Proposition 2.3.2(2).Since p is a bounded measure, Ip I(A,,)= lp I(0) = 0. Since v << p , limn+mv(A,,)= 0. This completes the proof. 0

6.1.12 Remark. Neither the assumption that v is real valued nor the assumption that p is bounded can be relaxed in the above theorem. Suitable examples can be provided in the framework of finite-cofinite field 9 on n = { l , 2 , 3 , . . .}.

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THEORY OF CHARGES

Now, we consider a sequence p,, n 2 1of bounded charges on a field 9 of subsets of a set s2. Let p on 9 be defined by

for F in 9.It is obvious that p is a bounded charge on 9.Further, p, << p for every n 2 1. The following theorem indicates that p is, in a sense, minimal with respect to the above property of absolute continuity.

6.1.13 Theorem. Let p,, n z 1 be a sequence of bounded charges on a field 9 of subsets of a set R. Let p be defined as above. Let u be any charge on 9 s u c h that p, << u for every n 2 1. Then p << u. Proof. Let E >O. Choose W z 1 such that 1 / 2 N + ' < ~ / 2 . Since p l , p 2 , . . . , pN are absolutely continuous with respect to u, there exists S > 0 such that Ipi(B)I < ( ~ / 2 ) ( 1 + Ipil(R)) for i = 1 , 2 , . . . ,N whenever B E 9 and IvI(B)<S. Now, if BE^ and Iul(B)<S, then

< & / 2 +E/2 = E . Hence p << v.

0

Next, we take up the study of singularity for charges.

6.1.14 Definition. Let p and u be two charges defined on a field 9 of subsets of a set 0. p and u are said to be singular if for every E >O, there exists a set D in 9 such that Ip I(D)< E and Iul(D")< E . If p and u are singular, we use the notation p I u. If p and u are positive charges, then p Iu if and only if p A u = 0. See Definition 2.5.1. 6.1.15 Remark. The following definition might seem natural as a notion of singularity. p and u are said to be strongly singular, if there exists a set D in 9such that IpI(D)= 0 = lvl(Dc).If this is the case, we use the notation pslu.

Some comments are in order about these two concepts.

6.1.16 Remarks. (i). p Iv if and only if Ip I I IuI. (ii). p Iu if and only if u I p . (iii). If p s l u, then ,u I u. But the converse is not true. Let s2= {1,2,. . .}

6.

165

ABSOLUTE CONTINUITY

and 9= P(R). Let p on 9be defined by

Let u be any 0-1 valued charge on 9 such that u ( A )= 0 for every finite subset A of R. Then p I u. But p and v are not strongly singular. Strong singularity and singularity coincide for measures on u-fields.

6.1.17 Theorem. Let 9 be a u-field of subsets of a set R and two measures on 9. Then p 1u if and only if ps 1u.

p

and u

Proof. "If" part is clear. "Only if" part. Let p I u . For each n 2 1, there exists a set D, in 9 such that Ip I(Dn)< 1/2" and IuI(DZ)< 1/2". Let D = lim sUPn+mD,. Then lp I(D) = 0. The proof is exactly similar to the one given in the proof of Theorem 6.1.6. Let E=lirnsup,,,D',. By a similar argument, it can be shown that IuI(E)= 0. Note that D" = lim infn+mD Z c lirn D', = E. So, Iul(D')=O. Hence p s 1 v . 0

As a consequence of the above theorem, we obtain Hahn Decomposition theorem for measures.

6.1.18 Corollary. (Hahn Decomposition Theorem for Measures). Let p be a measure on a u-field Yl of subsets of a set R. Then there exists a set D in 8 such that p (A)2 0

whenever A E

and A c D,

p (B) 5 0

whenever B E 8 and B c D".

and

Proof. By Lemma 2.5.5, p is either bounded below or bounded above. So, by Remark 2.5.4(ii), we have p=p+-pL-

and p + ~ p - = O .

Since p + ~ p - = O we , have p c I p - . By Theorem 6.1.17, there exists a set D in 3 such that pf(DC)= 0 = p-(D). From the definition of p + , it follows that p (B) 5 0 whenever B E 8 and B c D'. By a similar argument, it follows 0 that p (A)2 0 whenever A E Yl and A c D. This completes the proof. The following theorem is analogous to Theorem 6.1.8. This theorem also indicates that Definition 6.1.14 is a natural definition of singularity for charges in harmony with the corresponding notion used in Measure theory.

166

THEORY OF CHARGES

6.1.19 Theorem. Let 2l be a u-field of subsets of a set R and p and v two bounded measures on 2L Let 9be a field on R generating M. Then p L v o n % if and only if p l v o n 9. Proof. "If" part is obvious even without the assumption of boundedness of the charges. "Only if" part. Let p Iv on a. By Theorem 6.1.17, there exists a set D in 3 such that Ipl(D)=O=Ivl(D"). Let E > O . By Theorem 3.5.3, there exists a set A in 9 such that \pl(AhD)+Ivl(AhD)<~.Now, llpl(A)~ ~ I ( D ) I I I ~ I ( A A D ) < EHence . I,uI(A)<E. Further, ~ ~ v ~ ( A c ) - / v ~ ( D c ) ~ ~ Ivl(AChD")= lvl(AhD)<~.HenceIvI(A")<E.Thiscompletestheproof. 0

We end this section with some remarks. 6.1.20 Remarks. Let p, v and T be charges on a field 9 of subsets of a set R. (i). If v << p and Y I p, then v = 0. This can be proved as follows. Let E > 0. There exists S > 0 such that lv\(A)<E whenever A E 9 and ( p\(A)< 8. One can take S < E . Since v l p , there exists a set D in 9 such that Ivl(D)<S andIpI(D")<S.Therefore, Ivl(R)=Ivl(D)+lvl(D")<S+~ < 2 ~Since& . >O is arbitrary, Ivl(R) = 0. (ii). If p << T and v L T, then p I v. An argument similar to the one above can be presented here. (iii). Some additional properties of absolute continuity and singularity will be given in Section 8.5. 6.2 LEBESGUE DECOMPOSITION THEOREM In this section, we embark on proving Lebesgue Decomposition Theorem for charges using Riesz Decomposition Theorem for Vector lattices. Recall that the space ba(R, 9) of all bounded charges on a field 9 of subsets of a set R is a boundedly complete Vector lattice. First, let us examine how far the notion of singularity introduced for charges in Section 6.1 is related to the notion of orthogonality introduced in Vector lattices. 6.2.1 Theorem. Let p, v E ba(R, 9).Then p and v are singular if and only if and v are orthogonal in the vector lattice b a ( R , m . (Consequently, the notation used for singularity of two charges is consistent with the notation used for orthogonality of two elements in the Vector lattice ba(R, 9).) Proof. Suppose p and v are singular. Let E >O. There exists a set D in 9 such that lp [(D)< E and Ivl(D") < E . Consequently, (1p I A IvI)(R) =

6.

ABSOLUTE CONTINUITY

167

Inf {lp I(B)+ lvl(Bc); B E 8< 2 ~ Since . E >0 is arbitrary, it follows that lpl A1.1 = 0. This implies that p and v are orthogonal in the Vector lattice ba(S1,9). The converse can be proved similarly. 0 Now, we characterize absolute continuity in terms of notions of Vector lattices. For the following, one has to recall the definition of the orthogonal complement of S, S', for any subset S of a Vector lattice. See Definition 1.5.7.

6.2.2 Theorem. Let p , v E ba(R, 9).Then v << p if and only if v E { { p } ' } l . Proof. From the definitions { p } l = {T E ba(Q

9); TI p}

and {{p}*}' = {A E ba(Q, 9); A IT for

every T in b }'},

it follows that v E {{p}l}' if and only if v I T whenever T I p . Suppose v << p. Let T E ba(fl, 9)and T IF. We show that v IT. But this follows from Remark 6.1.20(ii). Conversely, let v E { { p } l } * . Since {p}* = {lp I}', we assume, without loss of generality, that v and p are positive. By Theorem 1.5.12, v=

V (vAnp). n2l

Since v A n p 5 v A ( n + l ) p for all n 2 1, the set function A on 9 defined by A (F) =limn+- (v A n p ) ( F ) , F in 9 is a charge on 9. Consequently, the lattice supremum v is precisely A, i.e. v(F) = limn+- (v A np)(F), FE9. Since v A n p ~ n p v, A n p << p for every n 11. Now, we show that the sequence v A np, n 2 1 of charges converges uniformly to v. For any F in 9, lv - v A npI(F)IIv - v A n p I ( 0 )= (v - v A n p ) ( n )= v(n)- (v A n p ) ( n ) which converges to zero as n + co. Hence v A np, n 2 1 converges to v uniformly. Since v ~ n <

6.2.3 Corollary. (i). If p l , (p1+ F 2 )

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THEORY OF CHARGES

(iv). I f p L 1 , p 2 , p € b a ( R , q , p 1 < < p a n d p 2 < < p , t h(epn ~ + p d < < p . (v). I f pn, n 2 1 is a sequence in ba(R, 9)converging to a p in b a ( R , 9 ) in the norm of ba(0, q and pn <( A for every n L 1for some A in ba(fl, 9), then p << A.

Proof. (i) and (ii) follow because {v}' is a vector sublattice of b a (Q 9 ). See (iii) follows from the fact that {v}' is a closed subspace of ba(R, 9). Theorem 1.5.19. (iv) and (v) follow from the fact that {{p}'}' is a closed vector sublattice of ba(R, 9). 0 Now, we have developed enough machinery to prove Lebesgue Decomposition theorem.

6.2.4 Lebesgue Decomposition Theorem. Let p and v E ba(0, 9). Then there exist v1, v 2 in ba(R, 9) having the following properties. (i). v = v 1 + v2. (ii). vl<< p. (iii). v z l p . (iv). I4 = b11+ I d . (v). I f v is positive, then v l and v 2 are positive. Further, any decomposition of v satisfying (ii)and (iii) is unique. Proof. By Theorem 1.5.8, { p } l and {{p}'}' are normal vector sublattices of b a ( n , 9 ) . By Riesz Decomposition theorem 1.5.10, for a given v~ ba(R, 9), there exist V I in {{p}'}' and v 2 in {p}' such that v = v 1 + v2. By Theorem 6.2.2, v 1 << p. Obviously, v 2 I p. Uniqueness of the decomposition follows from Theorem 1.5.10. By Remark 6.1.20(ii), it follows that v 1 Iv2. By Theorem 1.5.4(21) and (22),1v1= Iv1+ v21 = lvll +Iv21. Thus (iv) follows. (v) follows from the uniqueness of the decomposition and (iv). This completes the proof. 0 The above theorem gives a decomposition for bounded charges only. It is natural to enquire about the validity of Lebesgue Decomposition theorem for charges not necessarily bounded. We present some negative results. (See Notes and Comments for some positive results.)

6.2.5 Theorem. Let 9 be a field of subsets of a set R and v an unbounded real charge on 9. Then there exists a bounded charge p on 9 such that Lebesgue Decomposition theorem is not valid for v with respect to p. Proof. Let 4' = {Ft 6 ; IvI(F) < 00). 4'is an ideal in 9 Let 4 be a maximal ideal in 9containing 4'. Define p on 9by p(A)=O, if A E ~ , = 1,

if A g 4 and A E ~ .

6.

ABSOLUTE CONTINUITY

169

is a charge on 9. We claim that Lebesgue Decomposition theorem is not valid for v with respect to p. Suppose v = v1 + v 2 , where v 1 << p and v z I p . Since v 1 is real and p is bounded, v 1 is a bounded charge. See Theorem 6.1.10(iv). Since v z I p , there is a set E in 9such that 1v21(E')< 1 and p (E)< 1. Hence p (E)= 0. Consequently, E E 4;. Hence E'g 9'.Therefore, IvI(E') = m. v1 is obviously bounded on E" and v2 is also bounded on E'. Therefore, v is bounded on E' which contradicts Ivl(E') = 00. Thus the claim is established. p

6.2.6 Theorem. Let 9 be a field of subsets of a set R. Let v be any real charge on 9 such that \.\(A)= co for every non-empty set A in 9. Then Lebesgue Decomposition theorem for v is not valid with respect to any non-zero bounded charge p on 9.

Proof. Suppose there is a non-zero bounded charge p on 9 such that Lebesgue Decomposition theorem is valid for v with respect to p. Let v = v l + v 2 , where v 1 < < p and v 2 1 p . By Theorem 6.1.10, it follows that v1 is a bounded charge. As v 2 1 p , there exists a set A in 9 such that 1v21(A)< lp I(R) and Ip I(A') < lp I(R). Then A is a non-empty set on which 0 v2 as well as v l is bounded. This is a contradiction. 6.2.7 Remark. The charge given in Example 2.1.3(6)is a charge satisfying the condition imposed on v of Theorem 6.2.6. We end this section by deriving Lebesgue Decomposition theorem for measures on fields from Theorem 6.2.4. 6.2.8 Theorem. Let p and v E ca(R, 9).Then there exist v 1 and ca (a,9)having the following properties. (i). v = v l + v2. (ii). vl<
v2

in

Proof. By Theorem 6.2.4, we obtain v1 and v2 in ba(R, 9)with the above . V ~ ca(R, E 9). 0 properties. By Theorem 6.1.11, v 1 E ca(R, 9)Hence

6.3 RADON-NIKODYM THEOREM The aim of this section is to prove Radon-Nikodym theorem in the framework of charges. The proof is mainly based on Hahn Decomposition

170

THEORY OF CHARGES

thereom and involves only elementary calculations. In Chapter 7 also, we obtain Radon-Nikodym theorem for charges as a simple consequence of a result in V1-spaces. First, we establish some preliminary results.

6.3.1 Theorem. Let 9 be a field of subsets of a set R and E 7 0. Suppose p and v are two bounded charges on 9satisfying p (F) 2 - ~ / 2and u (F)2 - ~ / 2for every F in 9. Then there exists a set A in 9 and a simple function f on R having the following properties. (i). lp (E)I < E whenever E E 9 and E c A. (ii). Iv(F) - D 5, f dp I 5 E whenever F E 9 and F c A'. Proof. By Hahn Decomposition theorem (see Theorem 2.6.2), for any in ba(R, 9) and S > 0, there exists a set B(T,S) in 9such that T(E)2 -6

whenever E E 9 and E c B(7, S ) ,

7(E)I6

whenever E E 9 and E c (B(T,8))'.

7

and Let m be any positive integer

For k

= 1 , 2 , . . . , m, define

Let A = B,, A, = B,-l -Bm, A,-* = Bm-2-(Bmp1u B,), . . . , A 2= B1 -(B2uB3 u - - uB,) and Al = R-(Bl u B z u . - * uB,). Note that A, AI, A2, .. . ,A, are pairwise disjoint sets in 9with union = R. Let

(i-1)e

f = i=12()p.l(n)+&) c We show that A and f are the desired ones. Let E E 9and E c A = B,. Then

6.

ABSOLUTE CONTINUITY

171

Also, by the given hypothesis, p (E)2 - ~ / 2> -e. Consequently, Ip (E)]< e. Thus (i) is proved. Now, let E E g a n d E c A ' = A l u A 2 u . * . u A m .So, E=

m

m

i=l

i=l

u ( E n A i ) =u Ei,

whereEi=EnAifori=1,2,. . .,m.Notethatforeach2sism,EicAic Bi-l and so

On the other hand, for each 15 i 5 m, Ei c B; and so

Consequently, from the above two inequalities, we obtain

and

m

"

5 &/2+&/2 =E.

Consequently, Iu(E)-D j, f d p l s e . This proves (ii). The following theorem is a generalization of the above theorem.

0

172

THEORY OF CHARGES

6.3.2 Theorem. Let 9be a field of subsets of a set R. Let p and v be two bounded charges on 9 and E >O. Then there exists a set A in 9 and a simple function f on R such that (i). Ip (E)I< E whenever E E 9and E c A, and (ii). Iv(E)-DI,fdpI<E whenever E E 9 a n d E c A ‘ hold. Proof. In the notation of the proof of the above theorem, let B1 = B(p, ~ / 1 6 ) and B2= B(v, ~ / 1 6 )Let . pl, p2, v 1 and v2 be defined on 9by

pi(F) = p (Bi nF),

FE9,

PZ(F)= -EL (B?nF),

F E 9,

vl(F) = v(BZnF),

F€9,

vz(F)= -v(B; nF),

F E9.

and Note that p = p1 -p2 and v = vl- v2. Further, pl(F) 2 - ~ / l 6 , p2(F)2 - ~ / 1 6 , vl(F)2-&/16 and vz(F)r-&/16 for every F in 9. By Theorem 6.3.1, there exist A, in 9and simple functions fij on R such that

Ipi(E)I< ~ / 8 whenever E E g and E c Aij and

fi,. d p ; l s e / 8

Ivj(E)-D

whenever E

E and~ E c A i

E

for i, j = 1, 2. Let A = A11 u A12 u AZIu A22 and f = ( f l l - f 1 2 ) L 1 + (f21 -f22)1~e. We show that the A and f defined above are the desired ones. Let E E and~E c A . Then

E = E nA = (E n A l l ) u (E nA12) u (E nA24 u (E nA22) = Eli u El2 uEzi u Ezz

where Eij= E n A,, i, j = 1,2. Disjointizing Eii’sif necessary, we can assume, without loss of generality, that Eij’sare pairwise disjoint. In the following, we use the property that Eijc Aii for i, j = 1, 2. Now,

6.

173

ABSOLUTE CONTINUITY

Thus (i) is established. Now, let E E 9 and E c A".Then E c A; for i, J' 2. Observe that p2(En B1) = 0 = p l ( E n BE). So,

+

= 1,

v(EnBP)-D

+Ivz(EnB?)-D[ 5 4 ( ~ / 8= )~

EnBP

f~~dp21

/< 2E .

0

This completes the proof. We need a lemma before proving the main theorem of this section.

6.3.3 Lemma. Let 9 be a field of subsets of a set 0, E > O and k >O. Let .9)be such that p r O and - k p ( F ) - - E < v(F)< kp(F)+E for every F in 9. Then the following statements are true. (i). For every E ' > E , there exists a two-valued simple function f on 0 such that

p , v E ba(0,

k 2

k 2

+E

- - p (F)- E ' < v (F)- A (F)< - p (F)

for every F i n 9, where A (F)= D JF f dp, F E 5F. (ii). For every E ' > E , there exists a simple function g on s2 such that -E

< v (F)- 7( F ) < E

for every F in 9, where 7(F)= D

IF g dp, FE9.

174

THEORY OF CHARGES

Proof. (i). By Hahn Decomposition theorem, there exists a set A in 9such that ~ ( E ) ? - ( E ’ - E ) whenever E c A and E E ~ , and ~(E).(E’-E)

whenever E c A Cand E E ~ .

Let f = ( k / 2 ) I A - (k/2)IAc.Clearly, f is two-valued. Further, for any F in $,

k f d p =v(FnA)--p(FnA) 2 k 2

< - p (FnA) + E , and

k f d p = v(FnA‘)+-p(FnAc) 2

+-2k p (FnA‘).

5 ( F ’ -E )

Consequently, by adding the above two inequalities, we obtain v(F)-D

k f d p <-~(F)+E’. IF 2

One can establish, by a similar argument, the other inequality

k --p(F)-&’ E and n 2 1, there exists a simple function f,, on R such that

k --p((F)-&*
fn

k dp< 7 p ( F ) + ~ * 2

for every F in g.The avove assertion is true when n = 1, by (i). Using (i) again for the charge v( -D I(.,f l dp, we can show that the above assertion is true for n = 2 . The general argument is similar. Now, let E ’ > E be given. Find E * > E and n 2 1such that ( k / 2 “ ) p(R) + E * < E’. The corresponding f n is the desired function. 0 9 )

The following is the main theorem of this section which we call RadonNikodym theorem for charges

6.

ABSOLUTE CONTINUITY

175

6.3.4 Theorem. Let 9 be a field of subsets of a set R. Let p, u E ba(R, 9) be such that p is positive. Then the following statements are equivalent. (i). u << p. (ii). For each E > 0, there exists a charge A in ba(ll, 9)and a nonnegative number k such that

- k p ( F )5 A ( F ) 5 k p ( F ) for euery F in 9,and I]u-A 11 5 E . (iii). For each E > 0, there exists a simple function f on R such that

for every F in 9. Proof. (i) 3 (ii). Without loss of generality, we can assume u to be positive. (We can argue separately for u c and u - . ) Let E > 0 be given. Since v << p, there exists S>O such that ~ ( E ) < E whenever E E and ~ p ( E ) < S . Let k = u ( n ) / S and A = u A k p . We show that A has the properties mentioned in (ii). Let F E 9.If p (F) < S , then u(F)- k p (F)5 u ( F )<E. If p (F)2 6, then v ( F )- k p ( F )Iu ( F ) - kS = u ( F )- u(R) 5 0 < E . In any case, we have u ( F ) - k p ( F )< E . SO,

1 1 -~ A 11 = Iu - A [(a)= Iu - u A k p I ( R )

~ ( n-(v) Akp)(R) {u(F")+ k p ( F ) ;F E .5F)

= (Y - u A k p ) ( R ) =

= u(R) -1nf

= Sup { u ( F ) - k p ( F ) ; F

E fl

5F.

From the definition of A, A 5 k p and A L 0. This proves (ii). ($3 (iii). Let E > 0. By (ii), there exists A in b a ( l l , 9 ) and a nonnegative number k such that

- k p ( F )5 A (F)5 k p ( F ) for every F in 9, and IIu -A

)I5 s/3. Then we have

- ~ / 3- k p ( F ) < A (F)< k p ( F ) + ~ / 3 for every F in 9. By applying Lemma 6.3.3(ii) for ~ ' = 2 ~ / there 3 , is a simple function f on ll such that

176

THEORY OF CHARGES

for every F in 9. Consequently, for any F in 9,

1

v (F)- D

jFf & 1

5

Iv(F) -A

(F)I+ IA (F)- D

IF 1 f dp

< ~ / +32 4 3 = E . This proves (iii). (iii)+(i). Let E >O. Let f be a simple function on SZ such that

for every F in 9.Let k = max {I f(w)l; w E R}. Take S = ~ / 2 k (Assume, . without loss of generality, that k > O . ) We show that if F E9and p(F) <S, then Iv(F)I < E . Note that

I

~ / 2 >v(F)-D

f d p LIv(F)I- D

fdp

[ F I

Consequently, Iv(F)I < E . This proves (i).

0

6.3.5 Example. Exact Radon-Nikodym derivative may not exist, i.e. there may not exist a D-integrable function f (with respect to p ) such that

v(F)=D

I,

f dp

for every F in 9, in Theorem 6.3.4. Let R = {1,2,3, . . .} and 9the finite-cofinite field on SZ. Let v and defined on 9by

p

be

v(F) = 0, if F is finite, = 1,

p(F)=

c 21

keF

=1+

T,

1 1T , kGF

Note that

v<
if F is cofinite;

2

if F is finite, if F is cofinite.

If there is a D-integrable function f on SZ such that

6. u (F)= D

ABSOLUTE CONTINUITY

sFf d p for every F in

177

$, then

f dp

v({n})=O=D[ {n)

=

fb) p ({n1)

1 = f ( n ) ; for every n 2 1. 2 SO,

I

l=u(R)=D f d p = 0 , a contradiction. For every k 2 1, by Theorem 6.3.4, there is a simple function fk on 0, which can be constructed easily, such that Iv(F) - D lFfkd p 1 < l/k for every F in 9. It can be checked that limm,n+m D Ifm -fn 1 d p = 0. But there is no function f on R such that f n , n 2 1 converges to f hazily.

CHAPTER 7

V, -Spaces

We have come across some function spaces, namely b a ( R , 9 ) and in Chapter 2, where 9 is a field of subsets of a set 0. It seems ca(R, 9), difficult to describe the duals of these spaces. However, there are some important function spaces, namely V,-spaces, related to ba(i2,9) which are more tractable and which we study in this chapter. These spaces are closely related to L,-spaces introduced in Section 4.6. In Section 7.1, we introduce V,-norms for 1r p s 00 and establish their connection with the corresponding L,-norms. V,-spaces are presented in Section 7.2 and are shown to be Banach spaces. The duals of V,-spaces for 1s p < 0O are identified in Section 7.3. In the last two sections, strong convergence and weak convergence in V,-spaces for 1s p < 00 are characterized.

7.1 L,-SPACES-AN

OVERVIEW

Let 9 be a field of subsets of a set R and p a probability charge on 9, i.e. p is apositive charge on $with p (R) = 1.In Section 4.6, we have defined L,(R, 9, p ) = {f;f is a TI-measurable function on i2 and with a pseudo-norm 1s p <00, and

l fl1,

Ifl”

= (D

is D-integrable}

If[”

dp)l’, for

f in L,(R, 9, p ) , where

L,(R, g,p ) = {f;f is a TI-measurable real valued function on R and essentially bounded}

Ifl,

for f in L,(R, g,p ) . with a pseudo-norm llfllm = essential supremum of By identifying functions which are equivalent under the equivalence p ) as the space relation f - g if f-g is a null function, we form 2?,(R, 9, p ) with a norm 11 1, unambiguously of all equivalence classes of L, (R, 9, derived from the corresponding pseudo-norm on L,(R, 9, p ) for every 1s p 5 00. These normed linear spaces (2?,(R, 9, p ) , )I*)1, are not Banach spaces in general. See Remark 4.6.8. The V, spaces to be introduced in

-

7. V,-SPACES

179

the next section are precisely the completions of these Z,,-spaces (for 1sp<0O). In this section, we give an alternative description of Z,-spaces. This description provides a natural setting for the introduction of V,-spaces. We establish some preliminary results.

7.1.1 Lemma. Let a and b be two non-negative real numbers and 1s p < 00. Then (a + b ) P s a P t l - p + b p ( l - t ) l - -for p any O < t < 1. Proof. Let us treat the case 1< p O first. The function + b p ( l- t ) l - p , 0 < t < 1 has the following properties. (i). lim,,of(t) = 00 = limt+lf ( t ) . (ii). f ' ( t ) = 0 admits only one solution t = a / ( a + b ) . Therefore, f has a global minimum at t = a / ( a + b ) . Hence a f(t) 2 f(-) = (a +b)' for any 0 < t < 1. a+b 0 If p = 1 or a = 0 or b = 0, the desired inequality is obvious.

f(t) =

For a given field 9 on a set R, recall that 9 stands for the collection of all finite partitions of R in 9. Under the notion of refinement of partitions, 9 is equipped with a natural partial order L with respect to which (9, L) becomes a directed set. If F E S , we denote the collection of all finite partitions of F in 9 by PF.

7.1.2 Proposition. Let ( R , S , p ) be a probability charge space, i.e. (a,9,p ) is a charge space and p is a probability charge on 9. Let A be any real charge on 9 s u c h that A << p. Then the net of real numbers

is an increasing net for any 1S p < 00. (If interpret 0 / 0 = 0.)

p (Fi)= 0,

then A (Fi) = 0 and we

Proof. It suffices to show that for any two disjoint sets A and B in 9,

If p (A) = 0 or p (B) = 0, this inequality is obvious. Let p (A)> 0 and p (B) > 0. In Lemma 7.1.1, let a = IA (A)I, b = IA (B)I and t = [ p (A)/p (A u B)]. Note that A is bounded. See Theorem 6.1.10(iv). Then 1- t = [ p (B)/p (A u B)]

180

THEORY OF CHARGES

Also, IA (A u B)I IIA (A)]+ IA (B)].Therefore,

0

This establishes the desired inequality.

Now, we introduce some notation. Let (a, 9, p ) be a probability charge space and A a real charge on 9such that A << p. For 15 p < 00, let

where the limit is taken over all P = {El, Ez, . . . , En}E 9. 11P

'p(Ei)]

; P ={El, EZ,. . . ,E,}E 9)

where the limit is taken over all P ={El, EZ,. . . , En}E 9.The equality of these four numbers is clear from Proposition 7.1.2. Note also that 0 IIlA Ilp 5 00. For B in 9, let A g be the charge on 9 defined by AB(A)= AfAnB), A E g.For A g , note that

Clearly, if A and B are disjoint sets in 9,then ~ ~ A +. !lABll: 4 ~ ~=~@(AuBdF.

7.1.3 Proposition. Let (a, 9, p ) be a probability charge space. Let A be a real charge on 9such that A << p. Then [[AI p = lllh Il l p for any 1I p < O3. Proof. If p = 1,then IIAllp = \A I(a)and lllA 111 = \A \(a). So, the desired assertion follows for this case. IA (F)I 5 IA I(F), it follows that IIAllp 5 Let 1< p < 03. Since for any F in 9, lllh I(Ip' It remains to be shown that lllh [[Ip IIlA \ I p . Let B E 9.From the definition of llABIIF, it follows that IA (B)/p (B)lpp(B) 5 llABll;. Consequently, IA (B)lS

7. V,-SPACES

181

I I A B I I ~ [(B)l(p~l)’p ~ = I l h ~ ~ ~ ~ [ p ( B ) ] ~ / ~l ,/ w p h+el r/ eq = 1.(Notethattheconvention 0/0 = 0 is enforced.) Thus for any partition {El,EZ,. . . ,En}€PB, we have, by Holder’s inequality for finite sums (See Theroem 4.6.2.), IA i=l

5

i]: IIAE~II~[P(E~)I~/~

i=l

(i

5 i=l

l/P IIAE~IIL)

n

( c p(Ei))

l/q

i=l

*

Therefore, from the last observation made preceding the statement of this proposition, we obtain the inequality

Taking supremum over all partitions {El, Ez,. . . ,En} in PB,we obtain [[A I(B)IP5 IIA&[p (B)]’-’. Or, equivalently,

Now, for any partition {Fl, Fz, . . . , Fm}of R in 9,

By taking supremum over all partitions {F1, FZ,. . . , F,} in 9, we obtain lllh 1; 5 IlA 1,”. From this, the desired equality follows. We now give some properties of

11 [Ip *

introduced above.

Proposition. Let (R, 9, p ) be a probability charge space. Let 1 5 p < Let A, A1, A 2 be three real charges on 9 such that A << p, A 1
Proof. (i) and (ii) are obvious. (iii) can be established using Minkowski’s inequality as follows. (See Theorem 4.6.6.)If {El,EZ,. . . ,En}is any partition of l2 in S, then

182

THEORY OF CHARGES

Theref ore,

0

Hence IIA 1 + AzIIp 5 IIA iIlp + IIAzIIp.

Now, we come to the promised alternative description of Zp(fl,$, p ) .

7.1.5 Lemma. Let (fl, 9, p ) be a probability charge space and f a simple function on fl. Let A on 9 be defined by A (F)= D f dp, F E9.Then IlA 1; = D If 1” dp for every 1 5 p < 00. Proof. Let f =I:=,aiIEi for some real numbers a l , u 2 , . . . , a,, and some partition {El, EZ,. . . , En}in P. Then

Also,

Further, if we take any partition {F1,F2,.. . ,Fm} in P finer than {El, Ez, . . . , En},then we have

Consequently, IlA 1:

=

zYXllailpp(Ei).This completes the proof.

0

7.1.6 Theorem. Let 1~p < 00. Let (a,9,p ) be a probability charge space and f E L,(n, 9, p ) . Let A on 9 b e defined by A (F)= D jF f dp, F E $. Then

D

I

Ifl”d P = IIAIIF.

Proof. First, let us treat the case p = 1. From the definition of lA111, it is clear that llA1ll = IAl(fl). By Theorem 4.4.13(xi), IA l(fl) = D If1 dp. dp. Now, we come to the case 1< p <00. We show that llAIIF I D 5 by Let the positive number q satisfy l / p + l / q = 1. Then for any E in 9, Holder’s inequality,

If[”

7. V,-SPACES

183

Let {El, E2, . . . , E,}E 8.Then

i=l

lwl”p(Ei) p(Ei)

[IAI(Ei)]P[p(Ei)]l-”

= i=l

=

: I Ifl”

i=l

D

Ei

dP = D

5 lfl”

dp.

Consequently, the inequality llAll;~DJ Ifl” d p follows. Now, we show the desired equality. Since simple functions are dense in L,(R, 9, p ) (see Theorem 4.6.15), there is a sequence f n , n 2 1 of simple D J -fl” d p = 0. For each n 2 1, let A, functions on il such that on 9 be defined by A,(F) = D JF f , dp, FE9T Then for every n 2 1, lllAnllp-IIAllpI(llhn -AllpS(DJ Iffl-fl” dp)l’”. Hence

If,

IlA 1;

=

lim Ilhnll; = lim D J I f n l p d p = D J If/” dp. n-tm

n-tm

The second equality above follows from Lemma 7.1.5. This completes the proof. 0

7.1.7 Theorem. Let (R, $, p ) be a probability charge space. Let 15 p < a. Then YP(&9, p ) = (A

E ba(il, 9); A (F)= D

I,

f dp, F

E

~

for some TI-measurable function f on R such that If 1” is D-integrable}.

0

Proof. This is now obvious from the results established above.

Now, we take up the case p = 00. Let (R, 9, p ) be a probability charge space and A a real charge on 9such that A << p. Let

5 a.We give below some properties of Obviously, 0 5 IIA )loo

11

*

IIm.

7.1.8 Proposition. Let (R, 9, p ) be a probability charge space and A, A I , A 2 real charges on $such that A c p , A l << p and A2<< p. Then the following statements are true.

184

THEORY OF CHARGES

(i). IlA llm= 0 i f and only if A = 0. (ii). llch llm= Ic 1 IlA llmfor any real number c. (iii). 1 + A2IIm 5 IIA 1IIm+ IIA2IIm. (iv)- IlA llco = 111A Illm-

Proof. (i), (ii) and (iii) are obvious. We prove (iv). IlA Ilm 5 Il1A (\loofollows from We show that l lo 5 IlA lloo.For the fact that IA (F)I5 IA I(F) for any F in 9. we have any B in 9 and {B1, B2,. . . , B,} in PB, m

m

i=l

i=l

C IA(Bt)I5 C I(h11mp(Bi)=IIhIImCL(B).

Hence 1A l(B) 5 Ilh ]lap(B), i.e., [IA l(B)/p (B)] 5 Ilh Itoo. Taking supremum we obtain Illrn5 IlA [Irn.This proves (iv). 0 over all B in 9,

7.1.9 Theorem. Let (0,9, p ) be a probability charge space and f a real valued T1-measurable essentially bounded function on R. Let A on 9 be defined by A (F)= D f dp, F E 9. Then

IF

llfllm

=Essential supremum off

= IlA

Ilm.

Proof. Note that f is D-integrable by Theorem 4.5.7 and consequently, A is well defined. First, we prove the inequality IlA llm5 Ilfllm. Let k be any positive number such that p * ( { w € 0 ;(f(w)l>k})=O. Then If15k a.e. [ p ] . Then by Theorem 4.4.13(vii),

Hence for any F in 9.

From the definition of Ilfllm, it follows that IIA llm 5 Il f l o o. To prove the reverse inequality, we proceed as follows. Let k = IlA I l m . Then \A I(F)5 k p (F) for every F in 9. This implies that D 5, -k ) dp 5 0 for every F in 9.We claim that l f l 5 k a.e. [ p ] . Define T on 9 by T(F)= D I, - k ) d p , F E9. Since T(F)5 0 for every F in 9, it follows from the definition of T + that T+(F)= 0 for every F in 9 and so, T-(F)= -T(F) for every F in 9. But T'(F) = D IF - k)+ d p for every F in 9. See k)+ is a null function. Theorem 4.4.13(xii). By Theorem 4.4.13(xiii), - k)+ - k ) - , it follows that - k 5 0 a.e. [ p ] . Since - k = Now, we claim that p *({w E R; If(w)I > k + E } ) = 0 for any E >0. Observe that k + - k)' and that - k)' is a null function. Therefore,

(If1

(If1

(If1

If1

(If1 (If1

(If1

p * ( { w E R; Jf(w)I > k

(lfl-

If\

(If1

+E})

s p * ( { w E R;

(If1

-k ) + > E } )

=O.

7. V,-SPACES

185

The claim is thus established. By the definition of Ilfllm, it follows that 11f)lm Ik + E for any E > 0. So, )Ifilm Ik . Hence 11f ) l m 5 IlA llm. This completes 0 the proof. In the above, we have indeed proved that [ f l s l l f l l m a.e. [ p ] if f is TI-measurable. Now, we provide an alternative description of Zm(R, 9, p). 7.1.10 Theorem. Let (R, 9, p ) be a probability charge space. Then Tm(fl, 9, p ) = [A

E ba(R,

.F); A(F) = D

1

f dp, F

E

~

for some essentially bounded TI-measurable real valued function f on R

I

Proof. This is now obvious.

0

.

7.2 Vp-SPACES Lk',-spaces, discussed in the previous section, are not Banach spaces in 9,p ) are not general, or, equivalently, the normed linear spaces zp(fl, complete in general. In this section, we introduce V,-spaces and show that they are the completions of the corresponding Tp-spaces for 15 p < 00. p ) be a probability charge space. For each 7.2.1 Definition. Let (R, 9, 1~p sco, let

v,(@9, I-L 1 = {A E M R , .F); 1, < 001. The following proposition is a consequence of Propositions 7.1.4 and 7.1.8. 1.2.2 Proposition. Let (R, 9, p ) be a probability charge space. Then for each 1 s p 5 co, (V,(R, 9, p ) , II-IIp) is a normed linear space. By Theorems 7.1.7 and 7.1.10, we have that Lk'JR, 9, p ) cV,(fl, 9, p) for every 1I p 5 00. Members of V,(R, 9, p ) need not admit exact RadonNikodym derivatives with respect to p. Now, we show that each V,-space is complete. 7.2.3 Theorem Let (R, 9,p ) be a probability charge space. Then for each 1Ip 5 co, (V,(R, 9, F ) , )I* \ I p) is a Banach space.

186

THEORY OF CHARGES

Proof. First, we treat the case 1s p
A (E)= lim A,(E) n+m

for E in 9.It is obvious that A is a charge on 9.Since A,,, n 2 1 converges to A uniformly over 9, A is bounded and A << p. It remains to be shown that A E V,(n, 9, p ) and that llAn -AllL,, n L 1 converges to zero. Let E > 0. There exists N r 1such that llh, - Amll; < E whenever n, m 2 N . Let P = {El, Ez, . . . , E k } E 9. Then for m 2 N,

Taking supremum over all P in 9, we obtain IlA -AmllFsE if m r N. This shows that A E V,(n, 9,p ) and that limm+m“Am -All, = 0. Hence (v,(n, 9, p ) , Il-II,) is complete for 1s p
5 IIAn -AmIImP(F)

5 IIAn -AmIIm*

This shows that A,,, n 2 l is a uniform Cauchy sequence over 9. Let A (F)= limn+, A,(F), F E 9.Then A is a bounded charge on 9and absolutely continuous with respect to p. It remains to be shown that A E Vm(n,9,p ) and that llhn-A il, n 2 1 converges to zero. Let E >O. There exists N 2 1such that ]]An -Amllm < E whenever m, n r N . Let F E ~Then . Ih(F)-A,(F)I=lim,,, Ih,(F)-hm(F)15~p(F)if m r N . Consequently, IlA - A r n l l r n s E if rn r N . This shows that A E Vm(n, g, p ) and \]A,, -All, = 0. Hence V,(n, 9,p ) is a Banach space. 0

7 . V,-SPACES

187

Now, we prove inclusion relations among V, -spaces. 7.2.4 Theorem. Let s S C O Then .

vl(n,

$9

(a,9,p ) be a probability charge space. Let

1s r 5

CL)=vr(fA 9, CL)~ V s ( 09, , P ) xVm(Q, 9, PI.

/Is

In fact, [(A111 5 IlA llr 5 IlA 5 IlA Jlmis valid for any real charge A on Babsolutely continuous with respect to p . Proof. Let 1s r <s 1be such that l/p Let P = {El, EZ,. . . ,En}E 9. Then

+ l / q = 1.

(by Holder’s inequality)

Hence IIA 11;s [llA Ils]s/p, or, equivalently, IlA [Ir 5 IlA IIS. If 15 s < co,then for any partition {El, EZ,. . . , En}in 9,

Hence IIAlls 11lA

Ilm.

This completes the proof.

0

The following is an interesting consequence of the above theorem. p ) be a probability charge space. For any real 7.2.5 Corollary. Let (a,9, charge A on 9absolutely continuous with respect to p,

lim Ilk IIp = Ilk Ilm.

P-m

Proof. By Theorem 7.2.4, limp+mIlA 1, certainly exists (may be equal to co) and is less than or equal to llAIIm. On the other hand, for any p > 1 and F in 9,

188

THEORY OF CHARGES

Now, we introduce simple charges. Recall that for any charge p on a field 9 of subsets of a set R and F in 9, p~ is the charge on 9defined by pF(E)= p ( E nF), E E9.

7.2.6 Definition. Let (R, 9, p ) be a probability charge space. A simple charge on 9 is any charge of the form aipE, for some real numbers a l , a2,. . . , a, and some partition {El,E2, . . . , En}in P. SC(R, 9, p ) stands for the collection of all simple charges on 9. SC(R, 9, p ) is a linear space and can be identified with the space of all simple functions on (R, 9) as follows. If f = aiIEiis a simple function on R for some real numbers al, a 2 , . .. , a , and some partition {El, EZ,. . . ,En}in P, then the charge A = u ~ on ~ 9Ehas~the property a i p is ~ a~simple that Ilfll, = IIA [Ip for every 1S p 5 co. Conversely, if A = charge on 9 for some real numbers al, a 2 , .. . ,a, and some partition {El, El, . . . , En}in 9, then the simple function f = I:=,u ~ I E on~R has the property that IlAll, = Ilfll, for every 1s p 5 co. It is obvious that SC(R,g, p ) c V,(R, g, p).

x:=l

Among simple charges, the charges given in the following definition are of special interest. 7.2.7 Definition. Let (R, 9, p ) be a probability charge space and A a real charge on 9 such that A << p . Let P = {El, Ez, . . . ,En}€8.Define A(Ei)

Ap=

1PEi. p(Ei)

i=l

It is obvious that

and

for any l s p
Next, we show that SC(R, 9, p ) is a dense subset of V,(R, g, p ) for any 15 p < 00. First, we need the following results.

7. V,-SPACES

7.2.8 Lemma. For any p > O and that

IX - 11’

> O , there exists a number k ( p , E ) such

E

2k (p,E)[[x

189

1’

+ p - 1 -PX]

+ IX 1’ E

for any real number x. Proof. The function f defined on the real line by f ( x ) = 1x1’ + p - 1 - p x ,

x ER

is continuous and positive for all x # 1. Further, lim~x~-,m Ix - lIp/f(x) exists and is finite. For the given E > 0, we can find 77 > 0 such that Ix - 11’ 5 E Ix 1’ whenever Ix - 11 5 77. This follows from the fact that the function g ( x )= Ix - Il”/lx 1’ for x E (0, co) is continuous at x = I . Since limlxl+ooIx - Il”/f (x) is finite, there exists 771 > q + 1 such that Ix - l l p / f ( x )is bounded on the set {x ; Ix I > q l}. Since Ix - ll”/f (x) is well defined and continuous on [-ql, 1- q ] u [ l + q ql], , it is bounded on this set. Hence we can find a constant k ( p , E ) such that

Ix - 11, 5 k ( P , E ) f ( X ) whenever Ix - 11 > q. In any case, we have

IX - 11’ 5 k ( p , E ) [ [ x 1’

+ p - 1 -PX]

+ E 1x1’

for all real numbers x.

0

7.2.9 Lemma. Let (Q, 9, p ) be a probability charge space and A E V,(Q, 9, p ) for some 1 < p < 00. Then for a given E > 0 , there exists a constant k ( p , E ) such that IIA

- APlli 5 k ( P , E

IIi - llAPII3 + E IlA IC

for any P = {El, Ez,. . . , Em}in 9’. Proof. Let P’ = {F1, Fz, . . . ,F,} be a partition in 9 finer than P. Let E > 0. Let k ( p , E ) be the constant provided by Lemma 7.2.8. Let 1 5 i 5 n be fixed. Then we can find 1 5j 5 m such that Fi c Ei. Consequently,

In Lemma 7.2.8, if we set x = A (Fi)/Ap(Fi),with the usual convention about O/O, we obtain

190

THEORY OF CHARGES

Using Ap(Fi)= [A (Ej)/p(Ej)]p(Fi) and IA (Ej)/p(Ej)l”p(Fi),we obtain

multiplying

throughout

by

By summing first over all those i E {1,2, . . . ,n } such that Fi c Ej for a given j E {1,2, . . . , m } and then summing over all j E {1,2, . . ., m } , we obtain

Since the above inequality is true for any partition P’ finer than P, we obtain

0

This completes the proof.

7.2.10 Proposition. Let (fl,9, p ) be a probability charge space and A = C:, aipEibe a simple charge on 9, for a partition P = {El, EZ, . . . Em}in

9 and real numbers a l , a2, . . . ,a,,,. Then for any partition P‘>P, IIA

-A ~

’ 1 =1 ~0

for any 1s p
0

Proof. Simply note that A - Ap’ = 0.

p ) be a probability charge space and A a 7.2.11 Proposition. Let (a,9, positive bounded charge on 9 s u c h that A << p. Then

lim IlA -(A

n-a

A

np)II1= 0.

Proof. Since ba(fl, 9)is a boundedly complete vector lattice (see Theorem 2.2.1) and A << w, A = Vnzl (A A n p ) . See Theorem 1.5.12 and Theorem 6.2.2. Note that limn+m(A A n p ) ( A )= A (A) for every A in 9, In particular, ( A -(A A n p ) ) ( R ) ,n 2 1 converges to zero, i.e. limn+m\\A -(A A np)II1= 0. This proves the result. 0 Now, we come to an important result of this section.

(a,9,p ) be a probability charge space. Then, for each 1‘ p < 00, the space SC(fl,%, p ) of all simple charges is a dense subset of V,(Q 9,p ) . More precisely, for any 1s p
7.2.12 Theorem. Let

7. V,-SPACES

191

Proof. Let us tackle the case 1< p 0, by Lemma 7.2.9, there exists a constant k ( p , E ) such that for any P in 9,

IIA -APll; 5 k(p, ~~Cll~llpP-ll~Pll;l+~Il~lI;. ~ = IlA A 1; p (see ~ the ~ remark ~ following Definition

Since limPEP~ > O is arbitrary, it follows that

7.2.7) and

E

Now, we come to the casep = 1.Let A be a positive charge in Vl(fl, 9, p). Then for any P in 9 and n 21, IIA -A&

5 IlA

- (A A np)II1+ ll(A A n p )- (A A n p )PI11 + II(A A n p )P - A p h

5 211A

- (A

A

np )I11 +

A

n p ) - (A A n p ) P h

(by the remark following Definition 7.2.7) 52

b - (A

A

np

)I11+ ll(A I, w )- (A

A

np ) P ~ \ z

(by Theorem 7.2.4). Since 0 5 (A A n p ) s n p and n p E Vz(fl, 9, p ) , it follows that (A A n p ) E V z ( f l , 9 , p ) . Therefore, by what we have proved in the first part, limPEBll(A A n p ) - (A A np)pll2 = 0. Hence, by Proposition 7.2.11,

p ) , write Now, it follows that limPEpIlA -Ap(ll = 0. For any A in V1(R, 9, Note that Ap=(A+)P-(A-)p. Hence limPEBIlA -APII1=O. This completes the proof. 0

A =A+-A-.

For a general bounded charge p, not necessarily positive, by defining V,-norms with respect to lpl, we can, in fact, obtain the above theorem for general bounded charges. The above theorem for p = l gives the Radon-Nikodym theorem of Section 6.3 for charges.

7.2.13 Corollary (Radon-Nikodym Theorem). Let $be a field of subsets of a set R. Let p and v be two bounded charges on 9 s u c h that v << p. Then for each E > 0, there exists a simple function f on R such that

for every F in 9.

192

THEORY OF CHARGES

We also obtain from the above theorem that V,(R, 9, p ) is the complep). tion of Lfp(R,9, Corollary. Let ( R , 9 , p ) be a probability charge space. Then V,(R, 9, p ) is the completion of Lfp(R,9,p ) for every 1 ' p
7.2.14

Proof. This is a consequence of Theorem 4.6.15 and Theorem 7.2.12. 0

7.2.15 Remark. We have refrained from making any statement about Lfm(R,9, p ) in the above corollary. It is not true that Vm(R,9, p ) is the p ) . The following example justifies this point. completion of Zm(R,9, We recall the example given in Remark 4.6.8. Let R = {1,2,3, . . .}, F the finite-cofinite field on R and p the charge on 9defined by 1 if A is finite, p(A)= n o A 2"'

c

1 2"'

1-

=2 -

n.AC

if A is cofinite.

We state a number of interesting facts about this ( R , 9 , p ) . 1. Lfl(R, 9, p ) is not complete. See Remark 4.6.8. 2. Any bounded charge v on 9 is absolutely continuous with respect to p. (Let&>O.Findm ~lsuchthatCn,,Ivl({n})<~.TakeS =C,,,p({n}).) 3. Vl(R, 9, p ) = ba(R, 9). 4. A real valued function f on R is T1-measurable (Tz-measurable) if and only if f ( n ) , n 2 1 converges. 5 . A real valued function f on R is essentially bounded if and only if f is bounded. 6. If a real valued function f on R is bounded, then \lflloo= Sup{If(n)l; n E W . 7. Lfm(R,9, p ) = c, the space of all convergent sequences of real numbers p ) is complete. equipped with the supremum norm. Thus Zm(R,9, 8. A bounded charge v on 9is in V,(R, 9, p ) if and only if v ( { n } ) / p ( { n } ) , n 2 1 is a bounded sequence of numbers. 9. Let v on 9be defined by

n even

n odd

For this v, there is no essentially bounded T1-measurable function f on R

f d p for every F in 9. J , 10. Z m ( R , 9 , p ) is a proper closed subspace of

such that v(F) = D

v,(R, 9, p ) is not the completion of 9 m ( R , 9, p).

Vm(fl,9,p). Thus

7. V,-SPACES

193

We need an analogue of Proposition 7.2.11 for V,-norms to establish some results on strong convergence in V,-spaces. This is acheived in the following.

7.2.16 Lemma. Let (R, 9, p ) be a probability charge space and v a simple Then positive charge on 9. lim (Iv - (v A np)llp= 0

n+a3

for any 1' p
=EL,

Proof. If v aipEifor some nonnegative real numbers a l , a 2 , .. . , a,,, and some partition {El, EZ,. . . , Em}in 8,then v 5 n p for sufficiently large n. Hence the above limit is zero. 0 7.2.17 Theorem. Let (R, 9 , p ) be a probability charge space and 1s p < 00. Let v be a positive charge in V,(R, 9, p ) . Then

Proof. Let P={El, EZ,. . . ,En}be any partition in 8.Then for any n L 1, IIv - (v

A

n p Ill, 5 IIv - vpll,

+ llvp - ( v p A np Ill, + ll(vP A np

- (v A n p

l,.

By Theorem 1.5.4(29), I(vp A n p ) - ( v A n p ) /5 Ivp- vI. Consequently, for n L 1, llv-(v ~ n ~ ) I l , ~ 2 l l v - ~ ~ J ~ , + J J v ~ -ByLemma7.2.16,OS (~~~np))),. lim sup,,a3 IIv - (v A np)llp5 21(v- vpllp+ 0. Since this inequality is true for all P in 8,by Theorem 7.2.12, we have limn-,m IIv -(v A np)llp= 0. This 0 completes the proof.

7.3 DUALS OF V,-SPACES In this section, we show that the dual of V,(Q .F,p ) for any 1s p < m is V,(R, 9, p ) , where l / p + l / q = 1.

7.3.1 Theorem. Let (R, 9, p ) be a probability charge space. Then the dual of V,(Q 9, p ) for any 15 p <00 is isometrically ismorphic to V,(R, g, p), where l / p + l / q = 1. Proof. Let l < p < 0 0 and l < q < 0 0 be such that l / p + l / q = l . Let v E V,(R, 9, p ) . We define a linear functional T,, on V,(R, 9, p ) as follows. Let A ~ s C ( R , 9 , p ) .Then A =ELlaipEi for some real numbers a l , az, . . . , a , and some partition {El,Ez, . . . , E m } in 8.Define T,,(h)= EL, aiv(Ei). T, is well defined on SC(n,9, p ) . Further, T, is a linear

194

THEORY OF CHARGES

functional on the linear space SC(n, 9, p ) . Observe also that

(by Holder’s inequality)

5 Ilk llPIlv114.

T,, can be extended uniquely as a continuous linear functional to V,(Q .!F, p ) since SC(Q g,p ) is dense in V,(R, 9, p ) . Let us denote this extension again by T,. T,, has the property: ITu(A)I

4I~114lIAllP

for any A in V,(R, .!F, p ) . Let us compute the norm of T,,. Obviously, IlT,lls IIvIIq.We shall establish there exists a simple the reverse inequality by showing that for any P in 9, charge A such that lT,(A)I = IIvpllqllhIlp. Then it would follow that I l ~ P l l q J l ~ I l= P

lTu(A)I s l l T v 1 l l i 4 l P

from which we obtain lIvpllq 5 llT,,ll for any P in 9. Hence IIvIIq 5 llTulland so, the equality ensues. Let Now, let P = {El, El,. . ,En}E 9.

.

for i = 1,2,,

. , ,n

and A =Cy=1 c i p ~ ,Then .

Let us calculate IlA .,1

Consequently, we have IT&

)I = 1(vplI,IlA [Ip’

7. V,-SPACES

195

Thus we have associated a continuous linear functional T, on V,(n, 9, p) for any given v E V,(Q, 9, p ) such that (IT,IJ= IIvl/,. The map v + T,, from V,(n, 9, p ) to V:(R, 9, p ) is a linear map and is norm preserving. This map is obviously one-to-one. In order to show that this map is onto, we proceed as follows. Let T be any nonzero continuous linear functional on V,(n, 9, p ) . Define We enumerate the properties a set function vT on 9by vT(F) = T ( ~ FF )E,9. of vT. (i). Since T is a linear functional on V,(n, 9, p ) , V T is a charge on 9. (ii). Since T is a continuous linear functional, VT is bounded. For, for any F in 9, IvT(F)I= IT(PF)I5 ~~T~~IIPFII~ s l l T b ( F ) SllTll. (iii). vT<< p. Let E >O. Take S = ~/11T11.If F E9 and p(F)<S, then IYT(F)I <E. (iv). v T ~ V q ( n , g , pLet ) . P={El,Ez,. . . ,E"}EP.Then

i=l

Hence llvT[[:1llT1F. Thus v.T E V,(n, 9, p ) . For this VT, TVT = T.Hence llvTll = IlTll. This completes the proof that V:(n, 9, p ) and V,(n, 9, p ) are isometrically isomorphic for 1< p
i=l

Thus T, is a bounded linear functional on S C ( n , 9 , p ) and SO can be p ) . We extended uniquely as a continuous linear functional on Vl(S1, 9, denote this extension again by T,. Then I T u ( ~ ) l Is I ~ l l m l l ~ I l ~

for every A in V1(R, 9, p ) . Consequently, llT,ll 5 Ilvllm. To prove the reverse ~ p(F)>O. Let ul= inequality, we proceed as follows. Let F E and

196

THEORY OF CHARGES

sign(v(F))/p(F) and az=O. Let A have

= U I ~ F + U ~ ~ F C Since .

llA1ll= 1, we

Since this inequality is true for any F in 9with p (F)> 0, we have

Hence llvllm I~ ~ T Thus v ~we ~ have . proved that llT,,ll=IIVllm. Hence, the map v + T, from V,(R, 9, p ) to V ? ( R , 9 , p ) is a linear map such that IlT,,ll= IIvllm. So, this map is one-to-one. In order to show that this map is an isometric isomorphism, it suffices.to show that for any p ) , there exists VT in given continuous linear functional T on Ll(R, 9, Vm(R,9, p ) such that T = T,,, The existence of vT can be established along the same lines as that of the case 1< p
7.3.2 Remark. Let (R, 9, p ) be a probability charge space and p > 1, q > 1 be such that l / p + l / q = 1. For each v in V,(R, 9, p ) , T,, defined p ) and for each A in above is a continuous linear functional on V,(n, 9, p ) ,T A is acontinuous linear functionalon V,(R, 9, p ) . Theduality V,(R, 9, between V,(R, $, p ) and V,(n, 9, p ) can be expressed by T u ( A = TA( v )

for every A in V,(R, g, p ) and v in V,(R, 9, p). For any parition P = {El, Ez. . . . , Em}in 9,

Thus we have shown that Tv(Ap) = TA(vP).Since limpEp"AP- Allp = 0 = lirnpEpIIvp- vll,, it follows that Tv(A)= TA(v) for any A in V,(R, 9, p ) and v in V,(n, 9, p ) . This argument also shows that

exists and is equal to T,(A) = TA(v) for every A in V,(n, 9, p ) and v in v m , 9, PI.

7 . V,-SPACES

197

7.4 STRONG CONVERGENCE In this section, we give some conditions for strong convergence in V,-spaces for 15 p < 00. First, we need the following result.

7.4.1 Proposition. Let (Sz,%,p) be a probability charge space and v a bounded charge on 9absolutely continuous with respect to p . Then for any l % p , pl, ~ Z < O O , t l , t z 2 0 with tl+t2= 1 a n d p =tlp1+t2p2, the inequality

11~11;-= l l ~ l l ~ ~ f 1 1 1 ~ l l ; ; ~ 2 holds. Proof. Let P = {El, Ez, . . . , En}E 9 and t l , t2> 0. Then

Applying Holder’s inequality to the numbers l / t l and l / t z , i.e.,

we obtain

5 IIvI12:111vI12z.

Since this inequality is true for every P in 9, we obtain

1.”,

5

The case t l = 0 or tz = 0 is trivial.

ll~Il,”:f111~ll~f2. 0

The following theorem provides a sufficient condition for strong conp ) for p > 1 in terms of strong convergence in vergence in V,(Q 9, V l ( Q %, p ) .

7.4.2 Theorem. Let 1< r 5 00. Let (a,%, p ) be a probability charge space p ) satisfying the following two and v, v,, n L 1 a sequence in Vr(Sz,g, conditions. (i). v,, n 2 1 converges to v in V1(Sz,%, p ) . (ii). Supnzl llvnllr Then v,, n 2 1 converges to v in V,(Sz,9, p ) for any 15 p
198

THEORY OF CHARGES

Proof. In view of Theorem 7.2.4, it sufficies to prove for the case r < m . Assume, also, without loss of generality, that v = 0. In Proposition 7.4.1, if we take p1= 1, p 2 = r, tl = (r - p ) / ( r - 1) and t 2 = ( p - l)/(r - l), then for every n L 1, 1l v 11p v, :-p)/(r-l) r(P-l)/(r-l) n p-Il

II

IIvnllr

I ~ ~ v , ~ ~ ~ - ~ ) / k - l )r ( p - l ) / ( r - l )

[SUPIIvnllrl nzl

0

IIv,llp = 0. This completes the proof.

By (i), it follows that

The following therorem is analogous to the Lebesgue Dominated convergence thereorem proved in Section 4.6. This result also gives a sufficient condition for strong convergence in V,(R, 9, p ) for p > 1in terms of strong convergence in V1(R,9, p). 7.4.3 Theorem. Let (i2,9,p) be a probability charge space and v, v,, n 2 1 a sequence in Vl(R, 9, p ) having the followingproperties. (i). v,, n 2 1 converges to v in V,(R, 9,p ) . (ii). lv,I S A for every n 2 1 for some A in Vp(i2,9, p ) with 1 s p
Proof. For the case p = 1, there is nothing to be proved. Let us assume p > 1. By (ii), it follows that each v, eVp(R,5F, p ) . By (i), it follows that v,(F) = v(F) for every F in 9. It also follows that limn+m(v,l(F) = IvI(F) for every F in 9.(Use the fact that 1 ~ ~ 1n, 2 1 converges to 1.1 in Vl(R, 9, p ) . ) Consequently, IvI < A . Hence v E V,(R, 9, p ) also. Assume, without loss of generality, that each v, is positive. From the lattice properties of ba(R, 9), for any m, n 2 1, we have (A A mp)(v, A m p )S A - v,. See Theorem 1.5.4(29).Therefore, from this inequality, we obtain 0 5 v, -(v, A m p )s A -(A A mp).

Hence llv, - (v, A mp)IlpI l(A - (A ll v - v n l l p s l l v - ( v

A

mp)llp Thus for any m,n 2 1,

~ m l . ~ ) l l p + l l ( v ~ ~ m l ~ ) - ( v n ~ m ~ ~ ) I I~pm+ ~ l l )( v- v , nllp

5 IIv - (v A

mp

)]Ip

A

m p ) - (v, A mp )11p

+ Ilk - (A

A

m p )IIp

Observe that for each fixed m 2 1, (vn A mp),n 2 1 converges to (v A m p ) in V1(R,5F, p ) . This follows from the inequality II(v A m p )- (v, A m p ) l l l s ((v- v,(I1 for every n L 1 and (i). Further, (v, A m p )Im p for every n 2 1. Consequently, by Theorem 7.4.2, (v, A mp), n 2 1 converges to (v A mp) in V,(R, 9, p ) for every fixed m 2 1. Therefore, for every fixed m L 1, 0 s lim sup I(v- v,IIp 5 I1v - (v A mp)llp+ 0 +(\A - (A n-m

A

mp

)IIp

7. V,-SPACES

199

Now, by letting m + 00, by Theorem 7.2.15, we have OsIim sup IIv - vnllp < O + O . n-W

Hence limn,, ))v- vnllp = 0. This completes the proof.

0

The following theorem gives necessary and sufficient conditions for strong p ) for 1< p <03. convergence in Vp(n,9, 7.4.4 Theorem. Let 1< p
Proof. (i). This follows from the inequalities

I I I ~ n I I p - I I ~ I l p l ~ I-vIIp I~n and (p--l)/p

lvn (F) - v (F)I 5 llvn - vllp[c~(F)I

5

lbn - vllp

for every F in 9. (ii). v is obviously a charge on 9.We show that u < < p and that V E V,(R, 9, p ) . Since ilvnllp, n 2 1 is convergent, there is a positive constant M such that llvnllps M for every n 2 1. From the definition of ~ ~ v nit ~ ~ , , follows that for any F in 9 and n I1,

Equivalently, we have the inequality Iv, (F)I IIIv,IIp[p(F)](p-l)'p5 M[p(F)]'p-l)'P. Letting n + CO, we obtain lv(F)(sM[p(F)(p-l)'p.From this, it follows that v << p. For any partition P = {El, E2, . . . ,Em}in 8,

Taking supremum over all partitions P in 8, we obtain IIvII;sMP, or v E Vp(R, 9, PI.

200

THEORY O F CHARGES

Now, for any n 2 1 and for any given E > 0, by Lemma 7.2.9,there exists a constant k such that for any partition P ={El, Ez, . . . , Em}in 9, we have IIv-v,llp

4lv-vPIIp +llvP-(vfl)Pllp +ll(v,)P-~flIlp

Observe that

and this converges to zero as n + 00 since limfl+mv,(F) in 9. Therefore, lim sup I I -~vfl1lp5 1 1 v- ~

= v(F)

for every F

+~+[~(II~II::-II~PII~+&II~II~I~’~

P I I ~

fl-47

for every P in 9.By taking limPEp,we obtain limsupIlv-v,llp~o+o+&IIvllp. n+m

Since & > 0 is arbitrary, we conclude that limfl+mIIv - vnllp= 0. This com0 pletes the proof. The following theorem gives a necessary and sufficient condition for p). strong convergence in V1(R, 9,

7.4.5 Theorem. Let (0,9, p ) be a probability charge space and v,, n 2 1 a sequence in Vl(R, 9, p ) . Then v,, n 2 1 converges strongly in Vl(fl, 9, p) if and only if v, (F),n 2 1 converges uniformly over F in 9. 0

7.5

WEAK CONVERGENCE

Weak convergence in V1(R, 9, p ) will be considered quite extensively in Chapter 8. In this section, we prove just one result about weak converp ) for 1< p COO. gence in V,(R, 9,

7.5.1 Theorem. Let 1 < p < CO. Let (a,9, p ) be a probability charge space p). and v,, n 2 1 a sequence in V,(Sl, 9, (i). If v,, n L 1 is weakly convergent to a v in V,(R, 9, p ) , then v(F) = lim,,+mv,(F) for F in 9 a n d sup,,^ llvnllp
7. V,-SPACES

201

Proof. (i) If v,, rz 2 1 converges to v weakly in V,(n, 9, p ) , then TA(v,), n 2 1 converges to T A ( v )for every A in V,(Cl, 9, p ) , where l/p + l/q = 1. For F in 9, let A = p~ which obviously belongs to V,(n, 9, p ) . Consequently,

v(F)=T,(A)= TA(v)=limn+mTA(v,) = lim Tv,(h)= lim vn(F). n+m

n+m

See Remark 7.3.2.It is well known that every weakly convergent sequence in a Banach space is norm bounded. See Thoerem 1.5.16. (ii). As in the proof of (ii) of Theorem 7.4.4,it follows that Y E V,(Cl, .9,p ) . Now, we show that v,, n 2 1 converges to Y weakly in V,(Q, 9, p). Let A E V,(Cl, 9, p ) and Thbe the continuous linear functional on V,(n, 9, p) induced by A, where l/p + l/q = 1. TA is determined on SC(Cl, 9, p ) by k k uipEifor some real = uiA(Ei),where 7 = the following rule. TA(7) We show numbers ul, uz, . . . , a k and some partition {El,E2, . . . ,Ek}in 9. . would then imply weak converthat T A ( v n n) , 2 1 converges to T A ( v ) This gence of Y,, n rl to v in V p ( f l , 9 , p ) . Observe that for any partition P = {F1,F2, . . . ,F,) in 9,

ITA ( v n

I I

-T A(v)

TA ( v n ) -

+ ITA

I

TA

T A ( ( v n )P)l

( ( v n )PI

( v n ) - TA

First, we let n + CO. Then we obtain

-T A (vP)l ((vn)P)l

+ IT A

(vP)

- TA

I

202

THEORY OF CHARGES

Since this inequality is true for any P in 9, by taking the limit over P E P and using Theorem 7.2.12, we obtain

This completes the proof.

0

7.5.2 Remark. Given a probability charge space (R, S,p ) , one can find a charge space (X, %, A ) in which % is a cr-field on X and A is a probability 8 such that V,(fl, 9 , p ) is isometrically isomorphic to measure on 5 9,(X, %, A ) for every 1S p S 00.

CHAPTER 8

Nikodym Theorem, Weak Convergence and Vitali-Hahn-Saks Theorem

Nikodym theorem for measures gives a necessary and sufficient condition for norm boundedness of a set of measures on a cT-field. Vitali-HahnSaks theorem for measures characterizes uniform absolute continuity in the space of all bounded measures on a cT-field. These results are useful in the study of weak convergence in the space of all bounded measures on a a-field. The exact analogues of Nikodym and VitaliHahn-Saks theorems are not valid for charges on every field. In this chapter, we seek the exact analogues of these theorems for charges by considering more restrictive fields and yet general enough to include a-fields as a special case. The presentation of this chapter is somewhat at variance with that of the previous chapters in the following sense. In the earlier chapters, we have obtained weaker versions of some results of Measure theory for charges valid on any field. In this chapter, we obtain exact versions of the above theorems by considering some special class of fields. Section 8.1gives the relevant background information about Nikodym and Vitali-Hahn-Saks theorems. Section 8.2 gives some examples to demonstrate that Nikodym and Vitali-Hahn-Saks theorems are not valid for charges on fields. Section 8.3 presents Phillips’ lemma which plays an important role in our quest in extending Nikodym and VitaliHahn-Saks theorems for charges on some special type of fields. Phillips’ lemma is also used in characterizing weak convergence of charges. Section 8.4 presents the desired extension of Nikodym theorem. Section 8.5 studies norm boundedness of a set of bounded charges in the light of uniform absolute continuity. Section 8.6 gives a decomposition theorem for a given set of bounded charges in terms of norm bounded sets and finite dimensional sets. Section 8.7 is mainly concerned with characterizations of weak convergence in the space of bounded charges. Finally, Vitali-Hahn-Saks theorem is extended to special fields in Section 8.8.

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8.1 NIKODYM AND VITALI-HAHN-SAKS THEOREMS IN THE CLASSICAL CASE One of the important problems in the study of the space ca(R, %) of all bounded measures on the o-field % of subsets of a set R is the identification of weakly sequentially compact subsets M of ca(R, %). A set of necessary and sufficient conditions for m to be weakly sequentially compact involves norm boundedness of m and uniform absolute continuity of m with respect to some A in ca(Cl,%). Nikodym theorem characterizes norm bounded subsets of ca(R, %) and Vitali-Hahn-Saks theorem deals with uniform absolute continuity.

8.1.1 Nikodym Theorem. Let % be a o-field of subsets of a set Cl. Let M be a subset of ca(R, 3).Then Sup {lp (A)I;p E M}< 00 for every A in % if and only if Sup {lip 11; p E M} < 00. For a proof of this result, one may refer to Dunford and Schwartz (1964, Theorem IV.9.8, p. 309). We will obtain this result as a corollary of a more general result we prove in Section 8.4 in this direction. It is worth noting that if Nikodym Theorem 8.1.1 is valid for every countable subset of M, then it is also valid for M. For Vitali-Hahn-Saks theorem, we need the following definitions.

8.1.2 Definition. Let 9 be a field of subsets of a set R and M c ba(Cl,9). Let A E ba(R, 9).M is said to be uniformly absolutely continuous with respect to A if for every E > 0, there exists 6 > 0 such that Iv(A)I< E for every v in M

whenever A E 9 and IA I(A)<6.

8.1.3 Definition. Let be a o-field of subsets of a set R and M c ca(R, a). M is said to be uniformly countably additive if for any sequence A,, n 2 1 of pairwise disjoint sets in % and e > 0, there exists a natural number N L 1 such that

12,

P (Ad

I<

&

for every n 2 N and p in M. Now, we state Vitali-Hahn-Saks theorem.

8.1.4 Vitali-Hahn-Saks Theorem. Let % be a o-field of subsets of a set R and pn, n 2 1 a sequence in ca(R, %) such that p,(A), n L 1 converges to a real number for every A in %. Define p on % by p(A) = n-m lim p,(A),

A E 3.

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THEOREMS

205

Then the following statements are valid. (i). M = {p,, n 2 1) is uniformly absolutely continuous with respect to A whenever A E ca(R, '21) and p , c A for every n 2 1. (ii). M is uniformly countably additive. (iii). p is a bounded measure on '21. The non-trivial part of this theorem is the conclusion (i) from which (ii) and (iii) follow easily. For a proof of this result, one may refer to Dunford and Schwartz (1964, Theorem 111.7.2, Corollary 111.7.3 and Corollary 111.7.4, pp. 158, 159 and 160). We also obtain this result as a corollary of a more general result we present in Section 8.8.

8.2 EXAMPLES In this section, we present two examples which illustrate the point that extensions of Nikodym and Vitali-Hahn-Saks theorems fail in the framework of charges on fields. The first example we give here is concerned with Nikodym theorem.

8.2.1 Example. Let R be any infinite set and 9 the finite-cofinite field on SZ: Fix a sequence x,, n 2 1 of distinct points in R. For each n L 1, define pn on 9by n, if A is finite and x n E A, pn (A)=

I

0, if A is finite and xn& A,

-n,

if A is cofinite and xn& A,

0, if A is cofinite and x,

E A.

It is easy to check that each p n is a bounded charge on 9 and that (p,,(A)I
A@)=

1 nd(A)2

c

7,

1 n c I ( A ) 2"'

= 1+

C

-

if A is finite, if A is cofinite,

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THEORY OF CHARGES

where I ( A ) = {n L 1; x, E A}. A is a charge on 9and each p, << A. The later statement can be verified as follows. Fix n 2 1 and let E > 0. Take 0 < 6 < 1/2". If A E 9 and A (A)< S , then A is finite and x,& A. Consequently, p,(A) = 0 < E . However, {p,, n 2 1)is not uniformly absolutely continuous with respect to A. The above examples also demonstrate that Nikodym and Vitali-HahnSaks theorems fail to hold in the space ca(f2,9), where 9 is a field of subsets of f2.

8.2.3 Remark. Nikodym theorem for positive charges on any field trivially holds whereas Vitali-Hahn-Saks theorem may not hold. For example, let f2= {1,2,3, . . .}, 9the finite-cofinite field on f2 and p,(A) = 1, if n E A, =0, ifn@A,AE$ for every n 2 1. Let p (A) = CnsA1/2", A E 9. Then p,(A) exists for every A in 9and p, << p for every n 2 1.But {p,, n 2 1) is not uniformly absolutely continuous with respect to p.

8.3 PHILLIPS' LEMMA In this section, we prove a lemma due to Phillips (1940, p. 525) which is basic in our study of Nikodym and Vitali-Hahn-Saks theorems. First, we need the following concept of semi-variation of a charge. 8.3.1 Definition. Let For F in 9,let

p

be a charge on a field 9 of subsets of a set f2.

C; (F)= SUP {Ip (E)\;E c F, E E 9).

C; is called the semi-variation of p. We give some properties of C;. 8.3.2 Proposition. Let p be a charge on a field 9 of subsets of a set f2 and C; its semi-variation. Then the following statements are true. (i). C;(E)5 C; (F) whenever E, F E 9and E c F. (ii). C; (Eu F) IC; (E)+ C; (F) whenever E, F E 9. (iii). C; (E)5 lp ((E)5 2C; (E)for any E in 9.

8.3.3 Phillips' Lemma. Let f2={l, 2 , 3 , . . .} and S=P(f2),the class of all subsets of f2. Let p,, n 2 1 be a sequence of bounded charges on 9. In the following, ( i ) j (ii)@(iii).

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207

(i). limn+mp,(A) = 0 for every A in 9. (ii). limn-tmSup {Ip,(A)[;A c R, A finite}= 0 , i.e. p,, n 2 1 converges to 0 uniformly over all finite subsets of R. (iii). Iimn+mC k Z l lpn({k})l= 0. In particular, if (i) holds, then p,({n}) = 0.

Proof. (i)j (ii). This is proved in the following steps. 1". Given any integer m o r 1 and E > 0, we can find n o 2 1 such that lp,,({k})l<E whenever n 2 no. For this, use limn+mIp,,({k})l=0 for each k = 1 , 2 , . . . ,mo, from (i). 2". Suppose (ii) is not true. Then there exists 77 > 0 such that for any given m r 1, there is an m' 2 m and a finite set A c R such that Ip,,,,(A)Ir 277. 3". We develop some notation. If A is a finite subset of R, let min (A) stand for the smallest element in A and max (A) for the largest element in A. 4". We claim that for any given integer p 2 1, 7 given above in 2" and any integer 41 2 1, there is an integer 4 r q 1 and a finite set A c R such that p 5 min (A) and lpq(A)\2 77. The above claim obviously follows when p = 1 from 2". Suppose the above claim is false for some p > 1. Then there exists an integer q 2 2 1 such that for any 4 z q 2 and every finite set A c R with p ~ m i (A), n IpLq(A)I < 77 holds true. Since there are finitely many sets B c R having the property that max (B) < p and limn-tmp,,(B)= 0, we can find q3 2 1 such that Ipq(B)I< 77 .for every finite set B c R with max (B) < p and q 2 q 3 .Now, let q be any integer 2 max {q2,q3}. Let A be any finite subset of R. Let B = { i E A ; i < p } and C = { i E A ; i z p } . Then B n C = 0, B u C = A , max (B) < p and rnin (C)>p. Further, lpq(A)l= [pq(B)+pq(C)/ 5 lpq(B)I+ Ik,(C)l< 77 + 77 = 277. This contradicts 2". Hence the claim is established. 5". Now, we obtain two sequences n1 < n 2 < . and ml < m 2 < * * of positive integers and a sequence A,, n 2 1 of finite subsets of R having the following properties. (a). mi 5 min (Ai)5 max (Ai)< rni+l, i = 1 , 2 , 3 , . . . . (b). (pni(Ai)( r 7, i = 1 , 2 , 3 , . . . . (c). 121 Ipni({k})/<77/8, i = 2 , 3 , . . . . First, we obtain m l , A l , n1 and m2. Take m l = 1. In 4", take p = 1 and q1 = 1. We find an integer nl r q l and a finite set A1 t R such that m l = p 5 min (A,) and (pnl(A1)l 2 77. Let m 2= max (Al)+ 1. Using m2,we proceed to obtain A,, n2 and m3 satisfying (a), (b) and (c). In lo, take mo=m2 and E = q / 8 . We can find nk 2 1 such that Ip,,({k})l<77/8 for every n r n ; . In 4", take p = m 2 and q1= m a x { n ~ , n l } + l . We can find n 2 z q 1 and a finite set A2cR such that L 77. Note also that Cr2, lp,,&k})/< ~ / 8 . min (A,) 2 m 2 and Ipn2(A2))

x:Zl

-

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THEORY OF CHARGES

Using m3, as in the above, we can obtain A3, n3 and m4 satisfying (a), (b) and (c). Proceeding this way, we obtain the desired sequences. Observe that A,, n 2 1 is a sequence of pairwise disjoint sets. 6". Now, we find a sequence S,, n 2 1of infinite subsets of R and a sequence p1 < p z < * * * of positive integers with the following properties, (a)'. P k is the smallest element in s k , k 2 1. (b)'. Sk+lC s k -(Pk}, k 2 1. (c)'. f i n p , ( U i a S k + 1 Ai) 5 77/89 k 2 1. First, we obtain S1, p1 and Sz. Write R = Ti, where T,, n 2 1 is a sequence of pairwise disjoint sets and each Tj is infinite. We claim that there is a j 0 2 l such that f i n l ( U i e ~ , , A i ) < ~Suppose /8. not. For every j' 2 1, iinl(uis~, Ai)> 77/8. We can find, for each j 2 1, a set Bi C U I ~Ai T, such that Ipnl(Bj)l< q / S . Since pnl is a bounded charge on 9and Bj, j 2 1 is a sequence of pairwise disjoint sets in .F,limjem ,unl(Bj)= 0. This contradiction establishes the claim. Let S1 = Ti,. Let p1 be the smallest element in S1. Then p 1 # 1. For, if p1= 1, then q / 8 Aj) 2 lFn,(A1)l2 77, by 5"(b). This contradiction shows that p1 # 1. By decomposing S1 -(PI} into a countable number of pairwise disjoint infinite sets, as above, we can find an infinite subset Sz c S1-(PI} such that finp,(UiES2 Ai)5 q / 8 . Hence the desired S1, p1 and S 2 are obtained satisfying (a)', (b)' and (c)'. If p 2 is the smallest element in Sz, then p 1 < p z . Continuing this way, we obtain the desired sequences having properties (a)', (b)' and (c)'. 7". Let A = Ui2lA , . For any fixed i 2 1, write

ujzl

2fi,l(ujo~1

i-1

u A , u u A,. By 5"(b), Ipnpi(APi)177. Note that max ( u;.:APi) : < mpi-l+lI m p ( ,by Sob). A = A, u

j=l

B

Consequently, by 5"(c),

Since

jzi+l

8.

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THEOREMS

209

by 6"(c)'. Consequently,

3

>q-q/8-~/8=zq.

-

Since P I < p 2 < * np,< npz< * .Therefore, pnp,,pnpz,. . . is an infinite pnPi(A) = 0. The above subsequence of p l , p z ,. . . . So, by (i), inequality is a contradiction to this limit. Hence (ii) is valid. (ii)+ (iii). Note that a,

m

0 ~r lirn sup n+m

~r 2

C lpn({k})I= limn-msup rn-mk-1 lim 1 kzl

( p , ({k})I

lim sup Sup {lp,,(A)l;A c R and A finite} = 0, n-rm

by (ii). Hence (iii) follows. (iii)+ (ii). Note that 0 5 lirn sup Sup {(pn(A)I; A c n and A finite} n+m

5 lirn sup n-m

C

Ipn( { k } ) (= 0,

by (iii).

k z l

Hence (ii) follows.

8.3.4 Remark. In the above lemma, (iii)+(i) is not true. Take any sequence pn, n 2 1 of distinct 0-1 valued charges on P(R) each of which vanishes on finite sets.

8.4 NIKODYM THEOREM We develop this theorem in the framework of Boolean algebras. The various notions connected with Boolean algebras are given in Section 1.4.

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THEORY OF CHARGES

8.4.1 Definition. A Boolean algebra B is said to have Seever property if for every two sequences a,, n 2 1 and b,, n 2 1 in B satisfying the following conditions (i). a l s a z s a 3 * ~, ~ ~ (ii). bl? bz 2 b3 L * and (iii). a, b, for every m, n 2 1, there exists c in B such that a, s c 5 6, for every m, n 2 1.

-

Boolean cr-algebras and cr-fields of subsets of any set constitute an important class of Boolean algebras with Seever property. We give some examples.

8.4.2(i) Example. Let R = {1,2,3, . . .} and 9 the finite-cofinite field on $2.The Boolean algebra 9does not have Seever property. Take A, = { 2 , 4 , 6 , .. . ,2m},

m 21,

and

B , = R - { l , 3 , 5 ,..., 2n+1},

n ~ l .

There is no C in 9such that A, c C c B, for all m, n L 1. The following is an example of a Boolean algebra with Seever property which is not a Boolean cr-algebra.

8.4.2(ii) Example. First, we prove the following result. Let B1 and Bzbe two Boolean algebras and h onto homomorphism from B1 to Bz. If B1 is a Boolean algebra with Seever property, then Bz also has Seever property. Let a,, n 2 1 and b,, n L 1 be two sequences in BZsuch that a, 5 u,+l5 bm+l5 b , for all m, n 2 1. Let c,, n L 1 and d,, n L 1 be two sequences in Bl such that h(c,) = a n for every n L 1 and h(d,) = b, for every m L 1. Define e l = c1 A dl, f l = c1 v d l , f n t l = f , A (cnClv d,+l v e,) and e,+l = e , v ( c , + l ~ d , + l ~ f , ) ,n s l . Then e l 5 e z " * * " f 2 5 f l , h(e,)=a, and h ( f m )= b, for all m, n L 1. Since B1 has Seever property, there is an x in B1 such that e, s x sf, for all m, n L 1. Then a, Ih ( x )5 6 , for all m, n 2 1. This completes the proof. Now, we give the desired example. Let R = {1,2, . . .} and 9 the ideal of all finite subsets of 0. Since the natural homomorphism from P(R) to the quotient Boolean algebra P ( R ) / 9 is onto and "(0) has Seever property, by what we have proved above, P(R)/,9 has Seever property. We show that P(Q)/9 is not a Boolean a-algebra. Let B,, n 2 1 be a sequence of pairwise disjoint subsets of R each of which is infinite. Then Vnrl [B,] does not exist. This we prove as follows. Let [C]z[B,] for every n 2 1. Then we exhibit [D] in P ( R ) / 9 such that [C] > [D] 2 [B,] for every n 2 1.

8.

NIKODYM AND VITALI-HAHN-SAKS THEOREMS

211

Since B, - C is finite for every n 2 1, we can find a point x , in C n B , for every n L 1. Let A = {x,; n r 1)and D = C - A. This D serves the purpose. [B,] does not exist. Consequently,

v,

The most important result about Boolean algebras with Seever property is the following.

8.4.3 Theorem. Let B be a Boolean algebra with Seever property. Let p be any bounded charge on B. Let X = {b E B; lp 1(b)= 0). Then the quotient Boolean algebra B / N is complete.

Proof. Since B/X satisfies the countable chain condition, i.e. any family of pairwise disjoint elements in B / N is at most countable (because there cannot be more than n pairwise disjoint elements b in B such that Ip I(b)> l k l ( l ) / n ) ,it suffices to show that B/X is a Boolean c+-algebra.See Theorem 1.4.8. Let [a,], n 2 1 be a sequence of equivalence classes in B / N . We show that Vn,l [a,] exists in B/X. Without loss of generality, assume that a l r a 2 1 - * - . Let C = { b € B ; b r a , for every n r l } . Let r = Inf {Ipl(b);b E C}. Then there exists a sequence b,, n 2 1 in C such that r= Ip](b,).Without loss of generality, assume that bl 2 b22. * . Since B has Seever property, there exists c in B such that a, 5 c I b, for every m, n z 1. It is now obvious that V,,I [a,] = [ c ] . Thus B/X is a 0 Boolean c+-algebra.

-

Now, we are ready to prove Nikodym theorem for charges on complete Boolean algebras.

8.4.4 Theorem. Let B be a complete Boolean algebra and p,,, n 2 1 a sequence of bounded charges on B. Suppose for every b in B, Sup,,, Ipn(b)l< 00. Then Sup,,, llpnll< 00. Proof. Suppose Sup,,,, Ilp,ll= 00, i.e. Sup,,l SUPbeB Ip,(b)l = CO. First, we find a sequence c,, n L 1of pairwise disjoint elements in B and an increasing sequence mk,k r 1 of positive integers such that limk+mIpmk(ck)l= 00. For each a in B, define t, = Sup,,, SupbSa Ikn(b)l.Note that for each a in B, either t, = co or tl-, = co, where 1 is the unit element in B. For, if t, < 00 and tl-, < 00, then tl = Sup,,, SUpbeB Ip,(b)l < 00. Similarly, if t, = 03 for a in B, then either t b = co or t a - b = co for any b in B satisfying b 5 a. From the supposition that Sup,,,, Ilp,,ll=m, we can find m l z l and dl in B such that Ipml(dl)(>Supnrl Ip,(1)1+2. If tdl=co, t a k e e l = l - d l . We find that Iprn1(Cl)l=

I~rnl(1-dl)lz Ikrnl(dAl - I p m l ( l ) l

2 Ipm1(dl)l-SUPnz,

I/~n(1)1>2.

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THEORY OF CHARGES

If tl-& = 00, take c1= dl. In this case, we find that lprnl(cl)l= Iprnl(dl)l>2. In any case, we have Ipml(cl)l> 2 and tl-cl = 00. Since tl-E1= co,we can find dZI1 - c1 and m2 > ml such that (prn2(d2)1 > Sup,,l Ip,(1-cl)l+3. If t&=co, takecz=(1-c1)-d2. Note that Iprnz(cz)l= Iprnz((1

-cl)-dZ)I LIprnz(dz)I-Ipm,(l

-cI)I

~ I ~ r n z ( d 2 ) l -I pSn ~( 1~- ~ 1 ) 1 > 3 . nzl

If t(l-cl)-dz = 00, take c z = dZ.Now, Ipm2(c2)I = Iprn2(d2)I > 3. In any case, we observe that m2 > ml, C I A cz = 0, I p m l ( C 1 ) 1 > 2, IKrnz(Cz)l> 3 and tl-(clvc2)= 00. Continuing this procedure, we obtain a sequence c,, n L 1 of pairwise disjoint elements in B and an increasing sequence mk, k L 1 of positive integers such that limk--tmI/Arnk(Ck)l = a. For each k L 1, we define A k on P(R), where R = {1,2,3, . . .}, by

for A c R . Note that each Ak is a bounded charge on P(R). Further, limk,m &(A) = 0 for every A c a. This follows from limk+mI&,,(Ck)l= and SUpkzl Iprnk(ViE~ cj)l < 00 for any A c R. By Phillips' lemma 8.3.3, we conclude that limk,m Ak({k}) = 0. But hk({k}) = 1 for every k 1. This contradiction proves the result. 0 Now, we generalize Theorem 8.4.4 to Boolean algebras with Seever property.

Theorem. Let B be a Boolean algebra with Seever property and p,, n 2 1 a sequence of bounded charges on B. Suppose for every b in 5, Supnzl Ipn(b)l<m. Then Supnz1 I l p n l l < a .

8.4.5

for b in 5. Then A is a bounded charge on 5 and p, << A for every n 2 1. Let X = {a E B; A (a) = 0). Then, by Theorem 8.4.3, the quotient Boolean algebra BIN is complete. For each n z 1, define fin on 5 / N by fi,([bI) = p , ( b ) , b E B. Since pn << A, fin is well defined on B / N for all n L 1. Note that fin, n 2 1 is a sequence of bounded charges on 5 / N satisfying the hypothesis of Theorem 8.4.4. The conclusion of Theorem 8.4.4, now, gives the result. 0 The following is the main result of this section which gives Nikodym theorem for sets of bounded charges on Boolean algebras having Seever property.

8.

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THEOREMS

213

8.4.6 Corollary. Let M be any collection of bounded charges on a Boolean algebra B having Seever property. Suppose for every b in B, Sup {lp( b ) ] ; p E M} < 00. Then Sup {Ilpll;p E M} < a. Proof. Suppose Sup {IlpII;p EM}=00. Then we can find a sequence p,, n L 1in M such that sup,,^ I(p,ll = 00. By the given hypothesis, it is obvious that for every b in El, Sup,,, Ip,(b)l<m. This contradicts the validity of Theorem 8.4.5. 0 Of course, the classical Nikodym Theorem 8.1.1 follows.

8.4.7 Corollary. Let M be any collection of bounded charges on a u-field

9l of subsets of a set 0. Suppose for every A in a, Sup {Ip (A)I;p E M} < 00. Then Sup {lip 11; p E M} < 00. In particular, Theorem 8.1.1holds. 0

8.5

NORM BOUNDED SETS IN THE PRESENCE OF UNIFORM ABSOLUTE CONTINUITY

Nikodym theorem (Corollary 8.4.6) gives a set of necessary and sufficient conditions under which a given subset M of b a ( R , 9 ) is norm bounded when 9 is a field of subsets of a set R having Seever property. Now, we give a set of sufficient conditions based on the notion of uniform absolute continuity and strongly continuous charges, for a given set M c ba(R, .F)to be norm bounded without any conditions on 9. We need some preliminary results on absolute continuity, singularity and strongly continuous charges. We say that a bounded charge v on a field 9of subsets of a set R is atomic if v is a countable sum of two-valued charges on 9.

8.5.1 Proposition. Let 9be a field of subsets of a set 0. (i). I f p , v and T are bounded charges on 9such that p << v + T and p 17, then p v. (ii). I f p , v and T are bounded charges on 9such that p << v +T, then we can write p = p 1 + p 2 such that v and p2-x T. (iii). If p, v and T are bounded charges on 9such that p << Y + T and v I T , then we can write p = p l + p 2 such that p l << v and p2<< T , and such a decomposition is unique. (iv). If v is a two-valued bounded charge on 9 and p is any charge on 9 such that p << v, then p is two-valued. (v). If p is a strongly continuous charge on 9 and v is a bounded two-valued charge on 9, then p l u .

214

THEORY OF CHARGES

(vi). I f p is a strongly continuous charge on 9and v is a bounded atomic then p Iv. charge on 9, (vii). I f p and v are two bounded charges on 9 s u c h that v is atomic and p << v, then p is atomic. (viii). I f p and v are two distinct two-valued charges on 9, then p Iv. In fact, there exists A in $such that Ipf(A)= Ipl(R) and IvI(A') = Ivl(R). More generally, if vi, i L 1 is a sequence of distinct two-valued charges on 9,then p IA, where p = CisDaivi and A = pjvj, with D and E being disjoint subsets of {1,2,3,. . .}, C i s D Iail
xjeE

Proof. Without loss of generality, we assume that all the charges involved are positive. (i). Let E > 0. There exists S > 0 such that p (B) < ~ / whenever 2 B E 9and (v +r)(B) < 8. Assume, without loss of generality, that S < E . Since p 17, there is a set D in 9such that p (D) < S/2 and 7(DC)< S/2. Now, we show that p << v. Let C be any set in $such that v(C) < S/2. Note that p(C nD) < 6/2 < ~ / 2and (v + 7)(Cn D') = v ( C nD') + r ( C n D") < S/2 +S/2. So, p (C nD') < ~ / 2 Thus . we see that p (C) < E . (ii). By Lebesgue Decomposition Theorem 6.2.4, we write p = p1 +p~z such that p l<< Y and p 2 1I/.Clearly, p1 and p2 are positive. Now, p 2 5 p1+p~2
(iii). By (ii), we can write p = p 1 + p 2such that pl<O. There is a partition {Al, A2, . . . , A,} of R in 9such that p (Ai)< E for i = 1,2, . . . ,n. Since v is bounded and two-valued, v(Ai)=O for all but one i in {1,2, . .,n}, i.e. there is io in {1,2,. . . ,n } such that

.

=O<E

and p ( (

5 Ai))=p(Aio)<E.

i=l

Hence p I v. (vi). Since v is atomic, positive and bounded, we can write v aivi such that ai > 0 for every i L 1, CiZlai < co, vi is 0-1 valued for every i 2 1 and vi, i L 1 is a distinct sequence of charges. Let E > 0. Choose N 1 1 N such that CizN+lai < ~ / 2 .By (v), aivi. So, we can find D in 9 such that p(D) < ~ / 2 and ZEl aivi(D') < s/2. Now, v(D') = N aivi(DC)+Ci,N+l a i v i ( D ' ) < ~ / 2 + ~= / 2E . This completes the proof. (vii). By Sobczyk-Hammer Decomposition Theorem 5.2.7, we can write p = p l + ~ : !such that p l is strongly continuous and p2 is atomic. Since

lxi=l

xi=1

8.

NIKODYM AND VITALI-HAHN-SAKS THEOREMS

215

u. But by (v), p l lu. Hence p1 = 0. Therep1+p2<
Proof. We prove only (a) of (ii). Without loss of generality, we assume that all charges involved are positive. Let E > 0. Since M is uniformly absolutely continuous with respect to u, there exists 8 > 0 such that p (A) < e/2 for every p in M whenever A E 9 and u ( A )<S. We take S < E . We show that p1(A) < E for every p1 in M1 whenever A E 9 and ul(A) < S/2. Let A E 9and ul(A) < S/2. Let ~1 E MI. Note that, by Proposition 8.5.l(vi), p 1 1 u 2 . So, there exists D in 9 such <S/2. Note that pl(A nD) <6/2 <~ / 2 . that pl(D) < S/2 and v2(DC) Also, u(A nD") = vl(A nD") + u2(AnD") < S/2 + S/2 = S. Consequently, p(AnD')<&/2. So, p1(AnD")<&/2. Therefore, p1(A)= p l ( A n D ) + p1(A nD') < ~ / +2~ / =2E . This completes the proof. 0 Now, we prove the main theorem of this section. 8.5.3 Theorem. Let 9 be a field of subsets of a set R and M c ba(R, 9) be uniformly absolutely continuous with respect to a v E ba(R, S). (i). If u is a strongly continuous charge on P, then M is norm bounded, i.e. SuP{llPll;ELEM}<~. (ii). If every p in M is a strongly continuous charge ofz 9, then M is norm bounded. Proof. (i). Without loss of generality, assume that all charges involved are positive. Since M is uniformly absolutely continuous with respect to u, for E = 1, there exists S > 0 such that p(B) < 1 for every p in M whenever B E 9 and u(B) < 8.Since v is strongly continuous, there exists a partition (B1, B2, . . . ,Bk} of fl in 9 such that v(Bi) < S for i = 1,2, . . . , k. So, for k any p in M, p (a)= C,=l p (Bi)< k. Hence M is norm bounded. (ii). By Sobczyk-Hammer DecompositionTheorem 5.2.7, write u = u1 + u2, where ul is a strongly continuous charge on 9 and v2 is an atomic charge

216

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on 9. By Proposition 8.5.2(ii), M is uniformly absolutely continuous with respect to v l . (i) completes the proof now. 0

8.6 A DECOMPOSITION THEOREM Let 9 be a field of subsets of a set R and M c ba(R, 9) be uniformly absolutely continuous with respect to a v in b a ( R , q . In this section, we make an attempt to isolate that part of M which is responsible for the failure of M to be norm bounded. More precisely, we obtain a decomposition of M into a norm bounded part and a finite dimensional part. We start with a definition. N

8.6.1 Definition. Let A api,where v l , vz, . . . , vN are distinct 0-1 valued charges on 9 and a1, a z ,. . . , aN are any non-zero real numbers. A, is defined to be the collection of all bounded charges on 9 absolutely continuous with respect to A. Any subset of A, is called a finite dimensional set. 8.6.2 Remark. One can show that any p in A, is of the form pivi for some real numbers PI, p2, . . . ,pN. One can use Proposition 8.5.1 to establish the veracity of this statement. This is the reason for the use of the term “finite dimensional set”. The following proposition is instrumental in proving the main result of this section.

8.6.3 Proposition. Let 9be a field of subsets of a set R and M a subset of ba(R, uniformly absolutely continuous with respect to an atomic charge v in b a ( R , 9 ) . Then there exist two subsets MI and Mz of ba(R, 9)satisfying the following properties. (i). M1 and MZ are both uniformly absolutely continuous with respect to v. (ii). M c MI + M2 = { p + 7 ;p E MI, 7 E Mz}. (5).M1c A, for some finite linear sum A of 0-1 valued charges on 2F, i.e. MI is a finite dimensional set. (iv). MZis norm bounded.

Proof. The proof is carried out in the following steps. 1”.Without loss of generality, we can assume v to be positive. Since v is atomic, we can write v = Cizl aivi,where ai > 0 for every i 2 1,Cizl ai < CD and vi, i 2 1 is a sequence of distinct 0-1 valued charges on 9. (Iizl aiui could be a finite sum.)

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NIKODYM A N D VITALI-HAHN-SAKS

THEOREMS

217

2". Since M is uniformly absolutely continuous with respect to v, for E = 1, there exists S > 0 such that Ip [(B)< 1 for every p in M whenever B E 9 and v(B) < 6. N 3". There exists N 2 1 such that CizN+la; <S. Let A aivi and T = CizN+laivi.Note that ~ ( 0< S) and v = A + T . 4".Let (A1, A2, . . ,AN} be a partition of R in 9such that vi(Ai)= 1 for i = 1 , 2 , . . . ,N and vj(Ai)= 0 for every i Zj,i, j = 1,2, , , ,N. 5". Since the charges vi, i 2 1 are distinct, A IT. See Proposition 8.5.l(viii). 6". Let p EM. We can write p = p1+ p 2 , where p l and p2 are charges on 9, p1<
.

.

N

Ic~zl(R)=C IpZI(Ai) i=l N

=

N

C Ip2I(Fi)+i C= l i=l

1~21(Ai-Fi)

N

Note that for each i = 1 , 2 , . . . ,N, N

<0+6=S. By 2", IpL((Ai-Fi)
218

THEORY OF CHARGES

there exist two sets M1 and M2 contained in ba(R, 9)having the following properties. (i). M1 and M2 are both uniformly absolutely continuous with respect to v. (ii). M c M1+ M2. (iii). M1 c A, for some finite linear sum A of 0-1 valued charges on 9, i.e. M1 is a finite dimensional set. (iv). M2 is norm bounded. Proof. Assume, without loss of generality, that v is positive. Write v = v1 + v2, where v 1 is a strongly continuous charge on 9 and v2 is an atomic Write each p in M also as p 1 + p 2 , where p1 is a strongly charge on 9, continuous charge on 9 and p2 is an atomic charge on 9.Let H I = { p l ;p EM} and H2 = { p z ;p EM}. H1 and H2 are both absolutely continuous with respect to v and M c H1+&. By Proposition S.S.Z(ii>,HI is uniformly absolutely continuous with respect to v1 and H2 is uniformly absolutely continuous with respect to v 2 . By applying Proposition 8.6.3 to H2 and v2, we obtain two sets H3 and H4 contained in ba(R, 9)such that H2c H3 + H4, H3c A, for some finite linear sum A of 0-1 valued charges on 9and H4 is norm bounded. By Theorem 8.5.3(i), H1 is norm bounded. Take M1 = Hs and M2 = H1+ H4. MI and Mz are the desired sets. 0

8.7 WEAK CONVERGENCE Let 9 be a field of subsets of a set R. The principal object of study in this section is the space ba(R, 9)in its weak topology. It seems difficult, i.e. the space of all in general, to characterize the dual space ba*(R, 9), continuous linear functionals on the Banach space ba(R, In this section, we characterize weak convergence in ba(R,9). Recall that the weak topology on ba(R,9) is the smallest topology on ba(R, with respect to which all functions in ba*(R, 9)are continuous. The classical results on weak convergence in the space of bounded measures on a cr-field follow as simple corollaries of the results of this section. First, we give two results which are useful in characterizing weak convergence.

a.

8.7.1 Theorem. Let 4, pn, n L 1 be a sequence of bounded charges on a field $of subsets of a set R satisfying the following conditions. (i). {pn,n 2 1)is uniformly absolutely continuous with respect to 4. (ii). Supnal Ipn(F)I<W forevery F i n 9. Then Supna1 l l p n l l < 00.

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NIKODYM AND VITALI-HAHN-SAKS

219

THEOREMS

-

Proof. Suppose Supnzl Ilpnll= 00. We exhibit a sequence n l < n2 < * of positive integers and a sequence A,, n L 1 of pairwise disjoint sets in 9 such that Ipnk(Ak)l 2 1 for every k 2 1. Let r =Supnzl Ip,(R)l. Then r r+121. So, Ipnl(B?)ILbnl(fl)l- Ipnl(B1)ll2 Ipnl(B1)l- I C L , ~ ( R1.) ~ ~ Then either Sup,,l Ip,,I(Bd = 00 or Sup,,l lpnI(B;)= 00. If Sup,,l k&%) = co, take A1 = B;. Using the same argument given above for B1,we can find n z > n l and BZ in 9 such that Bz c B1, lp,(Bz)l 2 1 and Ipnz(B1 -B2)1 2 1 and so on. If Sup,,l Ip,,l(BT) = co,take Al = B1 and then work with B ; as above. Thus we obtain two sequences n l < nz < * * and A,,, n 2 1 of painvise disjoint sets in 9such that Ip,,(Ak)lL 1 for every k L 1.Since $ is bounded, limn,, $(A,) = 0. Hence p,, n 2 1 cannot be uniformly absolutely con0 tinuous with respect to $. This contradiction proves the result.

-

The above result can be labelled as Nikodym theorem for charges on fields. There are no conditions on the field but we impose an extra condition on the sequence F,, n L 1 to conclude that the set {p,, n L 1)is norm bounded. If p,,, n L 1 satisfies condition (i) only, it is not true that {p,, n 2 1) is norm bounded. As an example, let R = {1,2,3, . . .}, 9= 9(R)and p any 0-1 valued charge on 9such that p (A) = 0 for every finite subset A of R. Then the sequence { n p , n L 1) is uniformly absolutely continuous with respect to p but Sup,,l I(npII = 00. The argument presented in the proof of the above theorem is similar to the one used in the proof of Lemma 2.1.5.

Theorem. Let ( R , 9 , p ) be a probability charge space and p,, n L 1 a sequence in V1(R, 9,p ) such that {p,,, n 2 l} is uniformly absolutely continuous with respect to p and limn+, p,(F) = 0 for every F in 9. Then p,, n 2 1 converges to 0 weakly in V1(R, 9,p ) .

8.7.2

Proof. Let A E V,(R, 9, p ) .We show that limn.+, T A ( p , ) = 0. (See the proof of Theorem 7.3.1 for the definition of T A . ) Let E >O. There exists S > O such that lp,l(F)<~for every n L 1 whenever F E and~ p(F)<S. Since A E V,(R, 9, p ) , A E V1(R, 9, p ) . By Theorem 7.2.12, there exists Po = {F1,Fz, . . . ,F,} in 9 such that

{ C IA (Ej)- Ap,(Ei)l;P k

IlA

-Apolll

= SUP

i=l

= {El, Ez, .

I. ..

. . ,Ek} E 9 < SE.

Let r = Supnzl Ilpnll.By Theorem 8.7.1, r
220

THEORY O F CHARGES

Hence

Observe that

as n + CO, and

Therefore, limsup ) ~ ~ ( p n ) J s l i m JsTuAp- A p o ( p n ) J + O n +m

n+m

5 E [ r + 211A

llool.

Since E > 0 is arbitrary, it follows that limn-,.mT A ( p , ) = 0. This completes the proof. 0 The followingtheorem gives a comprehensive list of equivalent conditions for weak convergence of a sequence in ba(fl,9). 8.1.3 Theorem. Let S be a field of subsets of a set $2 and sequence in ba(fl,m. Let 4 on 9be defined by

pn, n 2

1a

8.

NIKODYM AND VITALI-HAHN-SAKS THEOREMS

22 1

for A in 9. Then the following statements are equivalent. (i). p,, n L 1 converges to 0 weakly in ba(S1, .9). (ii). C k z l p,(Ak) = 0 for every sequence Ak, k L 1 of pairwise disjoint sets in 9. (iii). limn-tmx k z l Ipn(Ak)l= o for every sequence Ak, k L 1 of pairwise disjoint sets in 9. (iv). limn-tmp, (A) = 0 for every A in 9and limn,, p, (A,) = 0 for every sequence Ak, k 2 1 of pairwise disjoint sets in 9. (v). limn-tmp,(A) = 0 for every A in 9 and {p,, n L 1) is uniformly absolutely continuous with respect to 4. (vi). lim,,,p,(A)=O for every A in 9 and { p n , n~ l is }uniformly absolutely continuous with respect to v whenever v E ba(S1, 9)and pn << v for every n L 1. (vii). p,, (A) = 0 for every A in 9and there exists a v in ba(S1, 9) such that {p,, n L 1) is uniformly absolutely continuous with respect to v. (viii). p,, n L 1 converges to 0 weakly in Vl(S1, 9,*). (ix). p,, n L 1converges to 0 weakly in Vl(S1, 9, v ) whenever v E ba(S1, .9) and p, << v for every n L 1. (x). There exists a v in ba(S1,9) such that p, << v for every n L 1 and p,, n 2 1converges to 0 weakly in V1(S1,9, v). Proof. (i)*(ii). Let Ak,k Define T on ba(S1, .9) by

L 1 be

a sequence of pairwise disjoint sets in 9.

for p in ba(R,9). Since IT(p)IsCkzlIpl(Ak)llpl(S1)=IIp1I,T is a continuous linear functional on ba(S1, .9). Since p,, n 2 1converges to 0 weakly in ba(S1, 9), lim T ( p n )= T ( 0 )= 0 = lim

1 p,(Ak).

n+05 k z l

n-tm

(ii)+ (iii). Let Ak,k L 1be a sequence of pairwise disjoint sets in 9. Define, for each n L 1, A, on P(N) by An(D)=

1

koD

pn(Ak)

for D c N, where N = { 1 , 2 , 3 , . . .}. Note that each A, is a bounded charge A,(D) = 0 for every D c N. By Phillips' lemma on P(N). By (ii), limn-+m 8 . 3 . 3 (i) (iii),

+

222

THEORY OF CHARGES

(iii)+(iv). Let A E ~ Take . Al = A , A z = 0, A3= 0, . . . . So, by (iii), limn-,wC k 2 1 Ipn(Ak)l= 0 = limn+wlpn(A)I. NOW, let A,, n L 1 be any sequence of pairwise disjoint sets in 9’ By .(iii),

This completes the proof of (iv). (iv)+ (v). Assume that (iv) holds and f i n , n L 1 is not uniformly absolutely continuous with respect to 4. This means that there exists E > O such that for every S > 0, we can find A in 9 and n 2 1 such that $(A) < S , but lpn(Nl2 28. For S = 1, we find A1 in 9 and n l L 1 such that lpnl(A1)l22.5 and $(Al) < 1. Since pl,p 2 ,. . . ,pnlare absolutely continuous with respect to $, there exists S1> O such that Ip,(A)I < .5/2’ for j = 1,2, . . . , nl whenever A E and ~ $(A)<S1. For S = S 1 , we find Az in 9 and n 2 ? l such that Ipn,(AZ)(2 2.5 and *(A2)< S1. Obviously, n2 > nl. Also, Ipnl(B)I< .5/2’ whenever B E 9 and B c A2, since $(B) 5 $(A2) < 81. Since PI, pz, . . . ,pnz are absolutely continuous with respect to 4, there exists SZ>O such that 2 =~ 1,2, . . . , nz whenever A E 9and $(A) < S2.For S = SZ, Ipj(A)I< ~ / forj we find A3 in 9 and n 3 2 1 such that IpCLn,(A3)]>2~ and $(A3)<82. 2 Ipn2(B)I ~ < &/Z3 whenever B E 9 Obviously, n3 >nz. Also, lpnl(B)I< ~ / and and B c A3, since $(B) 5 $(A3) < SZ. Proceeding this way, we obtain a sequence Ak, k L 1 of sets in 9 and a sequence n l < nz < * * * of positive integers having the following properties. (a). Ipnk(Ak)l2 2.5, k 2 1. (b). lpni(B)I< for j = 1,2, . . . , k - 1, k 2 2 whenever B E 9 and B C Ak. We relabel pnl,p n z , .. . as p l , pz,. . . . This is admissible since the property (iv) is hereditary, i.e. any subsequence of p,, n 2 1 has property (iv) . Now, we construct a sequence Hk,k 2 1of pairwise disjoint sets in 9and find a sequence 0 = p o < p l

(Hj+l)l> E

for every j L 0. This then gives a contradiction as property (iv) fails to hold for the sequence p l , ppltl, pp,+l,. . . , and the property (iv) is hereditary. First, we give H1 and p l . Let F1 = Al. If there is an integer i > 1 such that Ipi(F1nAi)l > ~ / 2 let , il be the smallest positive such integer and F2=F1-Ail. If there is an integer i > i l such that Ipi(FznAi)I>E/2, let i2 be the smallest positive such integer and F3 = Fz -Ai,. If this process does not stop at any finite stage, we get a sequence F1n Ail,F2nAi,, . . . of pairwise disjoint sets in 9such that ]pi*(FknAc)I > ~ / for 2 every k 2 1.This contradicts the validity

8.

NIKODYM A N D VITALI-HAHN-SAKS THEOREMS

223

of property (iv) for the sequence pi*, k z 1. So, let us assume that the above procedure stops at some finite stage. This means that there is a positive 2 every i >pl. Take H1 = Fpl.We integer p1 such that pi(Fpln Ai)5 ~ / for show that Ipl(H1)I2 2s - ~ / 2 . = IPl(Fp1-1 -AiplL1)I IPl(H1)I = Ip~(Fpi)l

= ICL1(Fp1-2-Ai,l-2-Ai.1-1)/

1~ 2 IP =

1(A1- Ail - Ai2 - * 1

-*

* *

-A

ipl-l

)I

(AllI - IP 1 (A1 Ail)I - IP 1 (A1 nAiJl * *

- Ipi(A1nAipl-,>l

- &/2’2- . . . - & / y P , - 1

2 2&- &/24

12E - & / 2 > & . Look at the sequence AI1)=Apl+l -FPlri r 1 and the sequence pI1)= ppl+i,i r l of charges. We claim that these sequences have properties similar to those of (a) and (b) with 2~ replaced by 28 - ~ / 2Note . that

IpL1)(AI1))I = IFpl+i(ApI+i-Apl+i nH1)1 2 Ippl+i(Apl+i)I - Ippl+i(Apl+in

z 2.5 - &/2 for every i r 1.

To prove (b), let B E 9 and B c A!’), i z 2. Then for j = 1,,2, . . . ,i - 1,

ICLjl)(~)I 5 &/2plCi I 3&/zi+l= 3 1 2 E F

1 2

= (2E - &/2)7.

Thus the sequences A!’), i 2 1 and p !I), i z 1 have the following properties. - ~ / 2for every i 1 1. (a)’. Ipi1)(A!1))122~ (b)’. Ipjl’(B)II(2.5 -&/2)(1/2’) for j = 1 , 2 , . . . ,i - 1, whenever B E 9 and B c A!” for i z 2. By using the argument given after (a) and (b) for the sequences figuring 2 ~ / 2 we ~ ,obtain an integer p 2 > p 1 , a in (a)’ and (b)’ and replacing ~ / by set H2 in 9 and sequences A!”, i z 1 and p?), i z 1 having properties ~ ( H2 ~~~) ~/ 2 -) ~ / 2 ’ . similar to (a)’ and (b)’. Further, lp!‘)(H2)I= I , U ~ ~ + 2 Observe that H2 c A\*)= APl+l-HI and so, HI n Hz = 0. Continuing this procedure, we get the desired sequences Hk, k 1 1 and pk, k r 0. Hence (iv)+ (v).

224

THEORY OF CHARGES

+

(v) (vi). It suffices to show that $ << v. But this is evident from Theorem 6.1.13. (vi)+ (v). This is obvious. (v) .$(vii). This is also obvious. ( v ) j (viii). This follows from Theorem 8.7.2. +) is a subspace of V1(R, 9,v). (viii)j(ix). By Theorem 6.1.13, V,(n, 9, Since p,, n 2 1 converges to 0 weakly in V1(R, 9, $), it follows that p,, n L 1 converges to 0 weakly in V,(n, 9, v). ( i x ) j (viii). This is obvious. (viii) (x). This is also obvious. (vii)+(x). This follows from Theorem 8.7.2. (x) (i). This is analogous to the proof given for the implication (viii)j(ix) because V1(Q 9,v ) is a subspace of ba(R, 9). This completes the proof that all the ten statements are equivalent. 0

+ +

Now, we formulate a theorem on weak convergence of a sequence of bounded charges analogous to the above theorem without specifying the limit. 8.7.4 Theorem. Let 9 be a field of subsets of a set n and p,, n 2 1 a sequence in ba(fl, Let $ be the charge defined on 9by

m.

for A in 9. Then the following statements are equivalent. (i). p, L 1 is weakly convergent in b a ( l 2 , a . (ii). p,,(A), n L 1 converges to a real number for every A in 9and {p,, n L 1) is uniformly absolutely continuous with respect to $. (iii). p,(A), n 2 1 converges to a real number p (A) for every A in 9, p E ba(R, 9)and {p, - p , n 2 1) is uniformly absolutely continuous with respect to $. Proof. (i)+ (ii). Let p,, n 2 1 converge to p weakly in ba(@ 9). Then p, - p , n L 1converges to 0 weakly in ba(n, By Theorem 8.7.3(i) .$(vi), lim,,oo ( p , -p)(A) = 0 and {p, - p , n L 1) is uniformly absolutely conwhenever p, - p << v for every n ? 1. tinuous with respect to v E ba(& 9) Note that {p,, n L 1)c Vl(n, 9,$) and Vl(n, 9, $) is a norm closed subspace of ba(R, 9). Consequently, Vl(s2, 9, $) is a weakly closed subspace See Theorem 1.5.17. So, p EV,(R, 9,$ Thus ).we observe of ba(R, By Theorem 8.7.3, that p, - p , n L 1converges to 0 weakly in V,(R, 9,$). {p, - p, n 2 1) is uniformly absolutely continuous with respect to sr/. Since p << $, {p,, n L 1) is uniformly absolutely continuous with respect to $. (ii) (iii). Let p (A) = lim,,oo p, (A), A E 9. Since {p,,, n 2 1) is uniformly

a.

a.

+

8.

NIKODYM AND VITALI-HAHN-SAKS

THEOREMS

225

absolutely continuous with respect to 4, p << 4. So, by Theorem 6.1.10(iv), is bounded. Consequently, {p, - p , n L 1) is uniformly absolutely continuous with respect to rfi. (iii)J(i). By Theorem 8.7.3(v)+(i), p, - p , n z 1 converges to 0 weakly . p,, n 2 1 is weakly convergent in ba(R,9). 0 in ba(n, 9)Consequently, p

Now, we show that if the field 9 has Seever property, characterization becomes very simple. of weak convergence of sequences in ba(R,

m

8.7.5 Theorem. Let 9 b e a field of subsets of a set n having Seever property and p,, n L 1 a sequence in ba(l2,m. Then p,, n z 1 is weakly convergent in b a ( Q 9 ) if and only if p,(A), n L 1 Converges to a real number for every A in 9. Proof. If p,, n I1converges weakly in ba(R, 9), by Theorem 8.7.3, p,(A), n 2 1 converges to a real number for every A in 9. This proves the “only if” part of the theorem. Conversely, let p(A) = limn+m@,(A), A E$. It is obvious that p is a Further, by Theorem 8.4.5, p is bounded. For each n 2 1, charge on 9. let v, = p, - p . For this sequence v,, n 2 1, we check the validity of (iii) of Theorem 8.7.3. Let Ak, k 2 1 be a sequence of pairwise disjoint sets in 9. For each n I1, define T, on P(N) by

for D c N, where N = {1,2,3,. . .}. Each T, is a bounded charge on S(N) and it follows that limn+ooT,(D) = 0 for every D c N. By Phillips’ lemma 8.3.3(i)+ (iii), lim

1

17,({k))l= 0.

n+m k z l

But ~ k ~ l 1 T , ( { k }=Ikzl )l Ivn(Ak)l. Hence v,, in b a ( n , 9 ) .

It

z 1 converges to

o weakly 0

Now, we obtain as a corollary the classical result on weak convergence of sequences of bounded measures on u-fields.

8.7.6 Corollary. Let 2l be a u-field of subsets of a set R and p,, It h 1 a sequence in ba(fl, 2l). Then p,, n 21 converges weakly in ba(R, 2l) if and only if p, (A),n I1converges ?o a real number for every A in 2l. In particular, if {p,, n 2 l }ca(R, ~ a), then p,, n 2 1 is weakly convergent in ca(R, a) if and only if @,(A),n 2 1 converges to a real number for every A in 2l. Proof. Note that every u-field has Seever property.

0

226

THEORY OF CHARGES

The results proved in this section give a new characterization of uniform absolute continuity.

8.7.7 Theorem. Let 9 be a field of subsets of a set R and p,, n I1 a sequence in ba(Q 9)Let . $ be the charge on 9 d e f i n e d by

for A in 9. Then {p,, n 2 1) is uniformly absolutely continuous with respect to if and only if for every sequence A,, n L 1 of pairwise disjoint sets in 9, limn+mpn(An) = 0. Proof. “If” part of this theorem is essentially the proof of the implication (iv)+ (v) of Theorem 8.7.3. We prove the “only if” part. Suppose for some sequence A,, n 2 1 of pairwise disjoint sets in 9, limn+mp,, (A,) # 0. Let E > 0 be such that lim Supn+mlpn(A,)[> E . Since pn, n L 1 is uniformly absolutely continuous with respect to $, for the E above, there exists 6 > 0 such that lpn(A)I< E for every n 2 1whenever A E9and $(A) <6. Since $ is a bounded charge, limn+m$(A,) = 0. So, there exists N L 1 such that $(A,) < 6 for every n IN . Consequently, ~p,,(A,,)~< E for every n 2 N . This implies that lim Supn+mIp,,(A,)I5 E . This contradiction proves the result.

8.8 VITALI-HAHN-SAKS THEOREM In this section, we obtain Vitali-Hahn-Saks theorem in ba(R, 9) for fields 9having Seever property. For this purpose, we introduce the notion of uniform additivity.

8.8.1 Definition. Let 9be a field of subsets of a set R and M c ba(R, 9). M is said to be uniformly additive if for any sequence A,, n I1of pairwise disjoint sets in 9, lim Sup 1 [p(A,)I=O. m+m

EM n z m

The following theorem gives equivalent versions of uniform additivity.

8.8.2 Theorem. Let 9 be a field of subsets of a set R and M c ba(R, 9). Then the following statements are equivalent. (i). M is uniformly additive. (ii). For any sequence A,,, n L 1 of pairwise disjoint sets in 9,

8.

NIKODYM A N D VITALI-HAHN-SAKS

THEOREMS

227

(iii). For any sequence A,,, n 2 1 of pairwise disjoint sets in 9, lim s u p s u p m-rw

&EM D c N

Ic

I

p ( ~ , = ) 0.

nzm

noD

Proof. It can be seen easily that each of the properties (i), (ii) and (iii) is hereditary, i.e. if M has any of the properties (i), (ii) and (iii), then any subset of M has the same property. (i).$(ii). This is obvious. (ii) (i). The proof is carried out in the following steps. Suppose (i) is not true. We show that (ii) is not true. 1". Since (i) is assumed to be false, there exist E >0, a sequence E,,, n 2 1 of pairwise disjoint sets in %, a sequence p,,, n P 1 of charges in M and a sequence jl<j z < * of positive integers such that

+

1 lp,,(Ej)l>~,

n = l , 2,....

i ?in

Since for any bounded charge p on 9, limm+mC,,,, Ip(E,,)I = 0, we can take p,,, n 2 1 to be distinct. 2". Look at p l . Since Ipl(Ej)I>E, we can find m l > j l such that x,2jlIpl(Ej)I> E . We can also find P I > ml such that Ipl(Ej)l< ~ / 4 . Now, for pp17 we can find m2 >j,, such that Ipp,(Ej)l> E and p z > m2 such that lppl(Ej)l< ~ / 4 . Continuing this procedure we obtain two sequences ml, m 2 , .. . and pl, p z , . . . of positive integers satisfying the following conditions. (a). jl< m l< p l I j,, < m z < p z s jm< m3 F , i = 1,2,3, . , . . (~1.Cjzpi+,I ~ p i ( ~ j ) l < ~ / i4 =, 1,293, * (We ignore p1.) 3". Look at the sets Ej,j = j,,, j,, 1, j,, + 2, . . . ,mz and p,,. By segregating ) 0, we can find those Ei for which pp,(Ej)< 0 and those for which p p , ( E j 2 F1, FZ,. . . ,Fkl,a subcollection of these Ej's, such that either cT1, pPl(Fi)< -&/2 with each pPl(Fi)< 0 or pp,(Fi)> ~ / with 2 each ppl(Fi)2 0. We can achieve this because of (b) for i = 1. Now, look at the sets Ei, j =j,,, jm+ 1, jm+ 2, . . . , m3 and p p z . By the same technique as above, we can find Fkl+l,Fkl+Z,.. . ,Fk2, a subcollection k of these Ei's, such that either Ci2kl+lppz(Fi)< - ~ / 2with each ppz(Fi)C 0 k or cj&l+l pp2(Fi)> ~ / with 2 each ppz(Fi)P 0. Continuing this procedure, we get a sequence F1,Fz, . . ,Fk,, Fkl+l, Fkl+Z,. . . , Fk,, Fkz+l,Fk,+Z, . . . , Fka. . . of pairwise disjoint sets in 9such that for each n 2 0,

cizjl

cjzp,

cizp,

-

+

.

I

k"+l

with the understanding that ko = 0.

I

228

THEORY OF CHARGES

4".We show that property (ii) fails to hold for the sequence ppl,p p z , .. . and the sequence F1, FZ,. . . of pairwise disjoint sets from g.This would prove the implication (ii)j(i). For every n L 0, note that

z

> €12- €14= €14. This follows from the elementary inequality la + b I L la1 - 161. Since k, -+ 00 as n + CO, property (ii) fails to hold for the sequence ppl,p p 2 ,. .with respect to the sequence F1, FZ,. . . of pairwise disjoint sets in 9. (i)j(iii). This is obvious. Let (iii)j(i). Let A,, n L 1 be a sequence of pairwise disjoint sets in 9. E >O. Since (iii) is assumed to be true, we can find m o r 1 such that for every m L mo,

.

SUP SUP

1c

D C N ~ E Mn z m nED

p(An)J< E / 2 *

Now, if m L mo and p E M, we have

c

nzm

c

c

nED

nsE

Ip(An)I=)n z m F ( A n ) l + /n z m p(An)l <E/2+

€12 = E ,

whereD={n rl;p(A,)rO}andE={n rl;p(A,)
8.

NIKODYM A N D VITALI-HAHN-SAKS

229

THEOREMS

Proof. (iii). It is clear that p is a charge on 5. Since p n ( b ) ,n 5 1 converges to a real number, Supnzl (p,,(b)l< CO. So, by Theorem 8.4.5, Sup,,, Ilpnll< 00. Hence p is bounded. (i). Since B has Seever property, by Theorem 8.7.5, F,,, n 2 1 is weakly convergent to some bounded charge T on B. Obviously, T = p. Define I,$ on B by

for b in B. By Theorem 8.7.4(ii), {p,,, n 2 1) is uniformly absolutely continuous with respect to $. By Theorem 6.1.13, 4 << u. Hence {pn,n ? 1) is uniformly absolutely continuous with respect to V. (ii). Since p,,, n L 1 converges to p weakly, p n - p , n L 1 converges to 0 weakly. By Theorem 8.7.3(i)J (iii),

for any sequence ek, k L 1 of pairwise disjoint elements in 5. Let There exists m l L 1 such that

2 ml.

>O.

b n ( e k ) - & (ek>l<E/2

k z l

whenever n

E

There exists m2L 1 such that

c

kzm

Ip (ek)l< E l 2

whenever m L m2. Let mo= max {ml, m2}.There exists N 2 1 such that

1

kzm

Ipi(ek)- (ek)l< E/2

whenever m L N and i = 1 , 2 , . . . , mo. Now, let m 2 N . Then kzm

Ipn(ek)15

C Ipn(ek)-p(ek)l+

kzm

c

kzm

Ip(ek>l

< E / 2 + & / 2= E for every n

5 1. This

shows that {p,,, n L 1) is uniformly additive.

0

The classical Vitali-Hahn-Saks theorem follows as a corollary. 8.8.5 Corollary. Let "I be a u-field of subsets of a set s1 and p,,, n L 1 a sequence in ba(s1, "I).Suppose p,,(A),n L 1 converges to a real number p (A) for every A in '$ Then I. the following statements are true. (i). {p,,,n zl} is uniformly absolutely continuous with respect to u whenever p,, << v for every n 2 1 for any v in ba(s1, fl),

230

THEGRY OF CHARGES

(ii). b,,, n 2 1) is uniformly additive. (iii). p is a bounded charge on 8. In particular, if bn, n 2 1) c ca(Cl, ? then, I)under , the above condition, the following statements are true. (i). b,,, n 2 1 ) is unifarmly absolutely continuous with respect to v whenever v E ca(S1, a) and p,, << v for every n 2 1. (ii). {p,,, n L 1)is uniformly countubly additive. (iii). p is a bounded measure on 8.

Proof. Every a-field has Seever property.

0

CHAPTER 9

The Dual of b a ( Q 9) and The Refinement Integral

One of the important problems in the study of the Banach Space ba(R, 9), the space of all bounded charges on a field 9 of subsets of a set R, is to This problem seems to be difficult and no describe its dual ba*(R, 9). is known. The satisfactory representation of the elements of ba*(il, 9) purpose of this chapter is to present one of the attempts made to describe using what is known as refinement integral. In Section 9.1, we ba*(n, 9) present some basic ideas on refinement integral. In Section 9.2, for superatomic fields 9, we show that refinement integral representation exists for We also show that the later property characterizes all elements of ba*(R, q. superatomic fields. We also obtain refinement integral representation for elements of VT(R,9, p ) in this section.

9.1 REFINEMENT INTEGRAL

9.1.1 Definition. Let 9be a field of subsets of a set R and p a bounded charge on 9. Let f be any real valued function defined on 9 and A E 9. Then the refinement integral off with respect to p over A is said to exist if there is a real number a with the property: for any E >0, there is a partition Po in PAsuch that for any partition P = {El, EZ,. . . , Em}of A in 9finer than Po,

If

i=l

f(Ei)p(Ei)-al

<E*

We write (Y =IAfp. (Recall that PAstands for all finite partitions of A in 9.) By the statement ‘‘IA fp exists”, we mean that the refinement integral off with respect to p over A exists. I f f = 1, then 5, fp exists for any A in 9 and any bounded charge p on 9andSafp=pCA). We give some basic properties of refinement integrals.

232

THEORY OF CHARGES

9.1.2 Proposition. Let 9 b e a field of subsets of a set Q and f a real valued function on 9. Let p and A be two bounded charges on 9 and A E 5F. (i). I f JA f p exists and p is a real number, then IA f/3p exists and JA fop =

p IAfp. (ii). I f

JA f

p exists and

I,f A

exists, then

IAf p + A

exists and

I,

f p +A =

I*fP +I*fA. (iii). I f f is a bounded function on 9 a n d J Afp exists, then

(iv). Let f be a bounded function on 9. Let p,, n L 1 be a sequence of bounded charges on 9 and a,, n 2 1 a sequence of real numbers such that Cnzl l a n l l p n l ( a ) < ~ . L e t p=Cnzl a,p,.If JAfp,exiStSforeueryn 21, then JA f p exists and JAfp=

c [ fpn. an

nzl

A

Proof. (i) and (ii) are obvious from the definition of the refinement integral. (iii). Let JA f p = a . Let E >O. Then there exists a partition P = {El,Ez, . . . ,En}of A in 9such that f (Ei)p(Ei)- a I < E . This implies that

Since E > 0 is arbitrary, we obtain

aipi,n L 1. By the given condition, A,, n 2 1 converges (iv). Let A, = to p in the norm of ba(R, 9). Note that, by (iii),

c

n z l

Let M = SupBEsI f (B)I and

E

I a n 1A f p n l < a *

> 0. We can find N

2

1 such that I(AN -pII <

9.

THE DUAL OF

b a ( R , 9 ) AND

REFINEMENT INTEGRAL

233

Further, we can find a single partition Po in PA such that for any patition P = {F1, F z , . . . , F,} of A in 9 finer than PO,

< ~ / +3N ( & / 3 N+) ~ / =3E . Hence J Af p exists and IAfP =

C

nz1

an

A

fpn.

0

We now show that every bounded real valued function on 9 for which the refinement integral with respect to p over R exists for every p in ba(R, 9)defines a continuous linear functional on ba(Q 9).

9.1.3 Theorem. Let 9be a field of subsets of a set R and f a bounded real valued function on 9.Suppose jn f p exists for every in ba(R, 9).Let T be defined on ba(R, 9) by

for p in ba(R, 9).Then T is a continuous linear functional on ba(R, 9). Proof. This follows from Proposition 9.1.2(i), (ii) and (iii).

0

The main problem considered in the next section is to characterize those fields 9 for which every T in b a * ( R , q admits a representation of the above type.

234

THEORY OF CHARGES

9.2 THE DUAL OF ba(Cl,F) Recall the definition of a superatomic field from Definition 5.3.4 for the following theorem. 9.2.1 Theorem. Let 9be a field of subsets of a set R. Then the following statements are equivalent. (i). Forany continuous linearfunctional Ton ba(R, 9), i.e. T E ba*(S2, 9), there exists a real valued bounded function f on 9such that ,5 f p exists for all p in ba(S2,9) and

w=[ nf P for all p in ba(S2, 9). (ii). 9 is superatomic. Proof. (i) j (ii). The proof is carried out in the following steps. 1". Suppose 9is not superatomic. By Theorem 5.3.6, there exists a strongly continuous probability charge A on 9. We define T on b a ( R , 9 ) by T ( p )= pl(S2)for p in ba(S2, 9), where p = p1+ p 2with p 1<< A and p21A. See Lebesgue Decomposition Theorem, i.e. Theorem 6.2.4. Since this decomposition is unique, T is a well defined linear functional. Continuity of T also follows from Theorem 6.2.4 if we observe that IT(p)l=IPCLI(WI5 IPll(W 5 IPllm + IP2l(n)

(I.

5 IP I(R) = 1 1 F

2". Since we are assuming that (i) holds, there exists a bounded function f on 9 such that T(p) = J n f p for all p in ba(S2, 3". For F in 9, let A F on 9 be defined by AF(E)=A(EnF)for E in 9. Then for any F in 9,

a.

I.

A(F)=AF(S2)=T(A~)= J fhF= n

r

JF f A .

(The Lebesgue decomposition of A F with respect to A is AF+ 0.) 4". Define 93 = {FE 9; every finite partition of F in 9 has a set B in 9 such that A (B) > 0 and f (B) 2 i}. 5". We claim that for every A in 9 with A (A)> 0, there exists F in 9such that F c A and F E 93. Suppose the claim is false. Then there exists A in 9 with A (A)> 0 such that F !ii93 whenever F c A and F E 9, i.e. for every either A (Bi)= 0 or f (Bi)< $ for all i. partition {B1, Bz, . . . , B,} of F in 9, By 3", since A (A) = JA f A , we can find a partition P = {Fl,F2, . . . ,F,,,}of A in 9such that

9.

THE DUAL OF

ba(fl, 9) AND

REFINEMENT INTEGRAL

Note that f(Fi)A(Fi)I$A (Fi) for all i, so that Therefore, A( ~ ) /5 2

If

i=l

235

f(Fi)A(Fi)IA (A)/2.

I

f(Fi)A( F i ) - A (A) < A ( ~ ) / 2 .

This contradiction establishes the claim. 6". Since A is a strongly continuous probability charge on 9, we can find Bo and B1 in .Fsuch that Bo nB1 = 0, A (Bo)> 0 and A (BI)>0. By 5", we can find A. c Bo and Al c B1 such that Ao, Al E 93. By the same argument, we obtain Aoo,Aol cAO; Alo,All CAI; AoonAol= 0; AlonAll= 0 and Aoo, Aol, Alo,All E 93. Continuing this way, we obtain{A,,,,,, ...,,,, ;~i = 0 or 1 for all i, n 2 l},a subcollection of 9 with the following properties. 6). A,,,,, ,..., 3AEI.E2 ,..., for all n 2 1. (ii). A,,,,, ,_... nA6,,6,.___. 6, = 0 if ( € 1 , E Z , . . . ,E , ) f (SI,SZ,. . . ,S,), n 2 1. 7". Let E = ( E ~ , E ~. ,. .) be a sequence of 0's and 1's. Let 8, = {A,,, A,,,,,, AE1,E2.E3, . . .}. Let 9,be a filter in $containing 8, and maximal with respect to the following property: (*) "For every A in 9€, there is a B in 93 n9, such that B c A." Existence of 9, can be established using Zorn's lemma as follows. We look at the collection % of all filters in 9 containing 8, and having the property (*), This collection is non-empty since the filter in 9generated by 8, (which exists by remark 1.1.23(4)) has the property (*). In the usual partial order of inclusion, one can show that every chain in % has an upper bound. Hence by Zorn's lemma, there is a filter 3, in 9containing 69€ and maximal with respect to the property (*). 8". Now, we claim that 9,is a maximal filter in 9. Suppose the claim is . 9;be the false. There exists C in 9 such that neither C nor C'E 9,Let filter in 9 generated by Seand {C} and 9f the filter in 9 generated by .!FEand {C?. In fact, En

9,' = { D E ~D; I C n B for some B in 9,} and

9:= {D E 9; D 3 C'n B for some B in 9,}. By the definition of 9,, 9;and 5Ff do not have the property (*). So, there are sets B1, B2 in gesuch that C n B1 and C'nBz do not contain any member of 93.We can assume that B1 = B2 = B, say, by considering BI nBz. By 5", A (C nB) = 0 = h(C'n B). This implies that A (B) = 0. But, since B E 9,, A (B) > 0. This contradiction shows that 9, is a maximal filter in 9. 9". We claim that if E = ( E ~ E, ~ .,. .) and S = (Sl, S2, . . .) are two sequences of 0's and 1's such that E # 8, then 9, and 9 6 are distinct. Suppose 9, =9 6 . Since E # S , there exists n 2 1 such that ( & I , E Z , . . . , E , ) # (61, SZ, . . . ,6,).

236

THEORY OF CHARGES

,,

So, A,,.,, n A,,.,, ..... = 0 E 9,a, contradiction. Thus the claim is valid. 10". We claim that for every n 2 1, { E E (0, l}Ko; A (A) 5 l / n for every A has at most n elements. (Recall that (0, l}Ko is the space of all in sE} sequences of 0's and 1's.) Suppose the above set has more than n elements. Pick up any n + 1 distinct elements E " ) , E " ) , . . . ,E ( n + l ) from this set. Since FEq 9,9. . . ,9,(n+1) are distinct, we can find Bi in Sc(:), i = 1,2, . . . , n + 1 such that B1, Bzr. . . ,B,,' are pairwise disjoint. Since A (Bi)5 l / n for every i = 1,2, . . .,n + 1,h(Urf: Bj)~ (+ ln) / n .But A (0)= 1.This contradiction establishes the claim. 11". Since

h (A) 2 l / n for every A E PE},

the set on the left is countable. Since (0, l}Nois uncountable, there exists q E {O,l}"o such that InfA,F,, A (A) = 0. 12". Let u on 9be defined by u ( A ) = 0, if A &9,,, A E 9,

=1, i f A E g V . u is a 0-1 valued charge on 9. 13". Observe that u LA. See Proposition 8.5.l(v). Hence the Lebesgue decomposition of u with respect to A is 0 v. Therefore, T ( u )= 0. 14". On the other hand, we show that J,fu>:. It suffices to show that

+

given P={E1, EZ,. . . , E m } in 9,there exists a finer partition P = (F1, Fa, . . . ,F,} in 9 such that I:=,f(Fi)v(Fi) 2;.For P = {El, Ez, . . . ,E m } in 9,there exists exactly one i, say i = 1, such that u(Ei)= 1, i.e. El E g,,. We can find B e F , , n B such that B c E 1 . Take P '= {B, EI-B, Ez, E3,. . * Em}. Thus 0 = T ( u )# J,fu 2 .; This contradiction shows that 9is superatomic. Now, we prove (ii)+ (i). This is carried out in the following steps. 1". We, first, collect some basic facts about derived sets in topology. Let X be any topological space and A c X. Set A' = A, A' (the derived set of A') = {x E A'; x is an accumulation point of A'}, if (Y is a limit ordinal, set A" = ADand for any ordinal a,set A"+'= (A")'. Then A", a 2 0 is a decreasing net of sets and each A" is a closed subset of A. For what follows, we assume that X is a scattered compact Hausdorff totally disconnected space. Then, there exists an ordinal (YO such that X"O is a non-empty finite set and Xn0+l = 0. This can be proved as follows. Let p be the least ordinal such that Xp = Xp+l. Then X p = 0.For, if Xp # 0 , then Xp+' is a proper subset of X p . (Since X is scattered, the 9

no<"

9.

THE DUAL OF

ba(R, 9)AND

REFINEMENT INTEGRAL

237

closed set Xp is not perfect and hence has isolated points in it.) Now, we claim that p = a O +1 for some ordinal ao. If p is a limit ordinal, then Xp = Xy= 0 and this implies that Xy= 0 for some y
nv
f (V) = SUP { T ( p1; p E V'}. If V = 0 ,let f (V) = 0. f is obviously a bounded function on 9. 4". First, we show that Jxfp = T ( p ) for any 0-1 valued charge p on 9. By lo,there exists a clopen set C c X and an ordinal po such that Cpo= { p } . Consequently, f(C) = T ( F ) C . also has the property: if E E 9and p E E c C, then EPo= E n Cpo= { p } .Now, for the partition {C, C"},we havef(C)p (C) + f (Cc)p(C") = T ( p )+ 0 = T ( p ) . Further, if P = {El, Ez, . . . , E,} is a refinement of {C, C'}, then CE,f(Ei)p(Ei)= T ( p )from the property of C mentioned above. Hence Jxfp = T ( p ) . 5". Let p be any bounded charge on 9. Since 9 is superatomic, p = Cnzl anpnfor some sequence I*.,,, n 2 1 of 0-1 valued charges on 9 and for some sequence an,n 2 1 of real numbers satisfying lan/<m. See the comment following Theorem 5.3.6. The conditions of Proposition 9.1.2(iv) are met and so lxfg exists and

IXfF= C

nzzl

an

I

x

fpn

=

C

nzl

anT(pn>

238

THEORY OF CHARGES

as C Z , aipi, n 2 1 converges to p in the norm of b a ( R , 9 ) and T is a continuous linear functional on ba(fl, 9). This completes the proof. 0 Now, we obtain a refinement integral representation for continuous linear p ) . For functionals on V1(R, 9,p ) for a probability charge space (a,9, relevant information on V1(fl, 9,p ) , see Chapter 7. 9.2.2 Definition. Let 9 be a field of subsets of a set R and p a positive bounded charge on 9. A real valued function f on 9is said to be convex with respect to p if

for every A, B in 9with A n B = 0. (Recall the convention that 0/0 = 0.) 9.2.3 Theorem. Let ( R , 9 , p ) be a probability charge space and T a continuous linear functional on V1(R, 9,p ) . Then there exists a bounded real valued convex function f on 9 such that T ( v )=In f v for every v in Vl(Q, 9, r*).

Proof. By Theorem 7.3.1, there exists a bounded charge A on 9 in Vm(R,9, p ) such that T ( v )= TA(v) for every u in V*(R,9, p ) . From Remark 7.3.2,

where P = { E l , E Z ,. . . , E m } is a generic element of 9. For F in 9, define f (F) = A (F)/p(F). Since A E Vm(R, 9, p),

Now, we check that f is a convex function with respect to p. For A, B in 9withAnB=0,

9.

THE DUAL OF

ba(R, 9) AND

REFINEMENT INTEGRAL

239

This shows that f is a convex function with respect to F. Now, for any in VI(R, 9, F),

Y

m

1 f(Ei)v(Ei)= PEPi=l

T ( v )= Th(v) = lim

n

fv,

where P = {El, E2, . . . , Em}is a generic element in 9.This completes the 0 proof. 9.2.4 Remark. We can obtain a refinement integral representation for F) for any 1 < p
CHAPTER 10

Pure Charges

A charge on a field may not be pure in the sense that there may be a part of it which is countably additive. If we isolate successfully a maximal countably additive part of a given charge, what is left may be termed as purely finitely additive. This chapter is devoted to the pursuit of these ideas. After presenting the preliminaries in Section 10.1, we prove a decomposition theorem due to Yosida and Hewitt in Section 10.2. In Section 10.3, we look at pure charges on a-fields. In Section 10.4, we discuss some examples which illuminate some aspects of pure charges. Finally, in Section 10.5, pure charges on Boolean algebras are studied.

10.1 DEFINITIONS AND PROPERTIES In this section, we introduce pure charges and give some of their properties.

10.1.1 Definition. A positive charge p defined on a field 9 of subsets of a set SZ is called a pure charge if there is no non-zero positive measure A on 9 satisfying A IF. More generally, a charge p on 9 is said to be a pure charge if lp 1 is a pure charge. Before characterizing bounded pure charges, we recall some results from Section 1.5 and Chapter 2. b a ( R , 9 ) stands for the vector lattice of all ca(R, 9) stands for the collection of all bounded bounded charges on 9. measures on 9 and is a vector sublattice of ba(SZ,9). We have already seen that b a ( Q 9) is a boundedly complete vector lattice and that ca(SZ, 9) is a normal vector sublattice of ba(SZ, 9). See Theorems 2.2.1 and 2.4.2. ca(R, 9)L stands for the set {A E ba(S1, 9); A 17 for every T in ca(0, Note that A 1~if and only if IAl A 171= 0. The following is a characterization of bounded pure charges.

m}.

10.1.2 Theorem. Let p E ba(R, 9).Then p E ca(n, 9)l.

if

p

is a pure charge if and only

10.

24 1

PURE CHARGES

Proof. Suppose p is a pure charge. Let 7 E ca(R, 9). Note that Ip I A 171Ilp I and Ip I A 17)I171. Since 171 is a bounded positive measure on 9, it follows that lp I A 171 is a measure. Since p is a pure charge, Ip I A 171= 0. Consequently, p 17.Hence p E ca(0,S)'. Conversely, let p E ca(fl, 9)l and A E ca(n, be such that (A 1 5Ip I. Since Ip I IIA I, i.e. Ip I A ( A I = 0, it follows that A = 0. Hence p is a pure charge. 0

a

The following is a simple characterization of a pure charge in terms of its positive and negative variations. 10.1.3 Corollary. Let p E ba(Q, 9).Then if p + and p - are pure charges.

p

is a pure charge if and only

Proof. Note that ca(R, 9)lis a sublattice of ba(0, 9). See Theorem 1.5.8. So, if p E ca(n, 9)', p + and p - c~ a ( R , 9 ) l . Conversely, if p + and p - ~ c a ( n , 9 ) * , then p = p + - p - ~ca(R, 9)'. 0 10.1.4 Corollary. Let p l , p 2 E ba(R, 9)and a any real number. I f p~ and p2 arepurecharges, s o a r e p 1 + p 2 , p l v p 2 , p1 ~ p a2n d a p l .

Proof. ca(R,9)' is a vector sublattice of ba(R, 9). See Theorem 1.5.8. 0 The following corollary shows that purity of charges is preserved under passage to limits. 10.1.5 Corollary. Let p, pn,n 2 1 be a sequence in ba(R, 9).Suppose for each n 2 1, pn is a pure charge and pn,n 2 1 converges to p under the total i.e. limn+.mlpn -pl(R) = 0. Then p is a pure variation norm on ba(R, 9), charge .

a'

a,

Proof. Since ca(R, is a normal vector sublattice of ba(R, it is closed. ConSee Theorem 1.5.19. Since each p,, is a pure charge, pn E ca(R, 9)'. sequently, the limit p E ca(R, 9)'. Hence p is a pure charge. 0

10.2 A DECOMPOSITION THEOREM The results developed so far yield the following decomposition theorem.

a

10.2.1 Theorem. A n y p in ba(fl, can be written in the form p = p p+ p,, where p p is a pure charge in ba(R, 9)and p , E ca(R, 9).Further, such a decomposition is unique.

Proof. This follows from the Riesz Decomposition Theorem, i.e. Theorem and S = ca(0, From Theorem 1.5.10 in which we take L = b a ( Q 9) 2.4.2, it is clear that S is a normal vector sublattice of L. 0

a.

242

THEORY OF CHARGES

We give another description of the countably additive part p, of p in the following theorem. 10.2.2 Theorem. Let p be a positive bounded charge on a field S o f subsets of a set a.Then for any A in 9,

p(A,); A,, n L l t A , A, €9, n21 = Inf

[1

p (A,); A,,

n 2 1 is a sequence of

nzl

pairwise disjoint sets in

with

U A,

nzl

=A

I

.

Proof. The equality of the two expressions on the right above is clear. For A in 9, let T(A)= Inf

1 p (A,); A,, n 2 1is a sequence of (nz1

pairwise disjoint sets in 9with

u A,

nz1

=A

I

.

Suppose v is any positive bounded measure on 9such that v 5 p. Obviously, v 5 T . Now, we show that T is a charge. Let A, B E 9be such that A nB = 0. Let E >O. We can find two sequences A,, n 2 1 and B,, n L 1 of pairwise disjoint sets in 9such that UnzlA, = A , UnzlB, = B and

Consequently,

7(AUB)s

C

P(An)+

C

p(Bn)

n2l

fl2l

+ T(B)+ E .

5 T(A)

Since E > 0 is arbitrary, it follows that T ( AuB) 5 T(A)+T(B).To prove the reverse inequality, we proceed as follows. Let E >O. We can find a sequence C,, n I1of pairwise disjoint sets in 9such that C, = A u B and p ( C n )~ T ( A B) u +E. nr1

10.

PURE CHARGES

243

But

Since E > 0 is arbitrary, it follows that T(A)+T(B)5 T(AUB). ConNext, we show that T is a measure. Let A,, sequently, T is a charge on 9. n I 1be asequence of pairwise disjoint sets in 9 s u c h that Unz1A, = A E 9. Since T is a positive charge on 9, C n , l ~ ( A n ) s ~ ( ASee ) . Proposition 2.1.2(viii). For any E > O and n 2 1, we can find a sequence Ani,i L 1 of Afli= A, and pairwise disjoint sets in 9such that

uizl

C

izl

P (Ani)I T(An) + ~ / 2 ~ *

Consequently,

T Wn1z l~iCz l p(Ani)snCz l T(An)+E. Since E > O is arbitrary, we obtain T ( A ) ~ 7(A,). C ~ Hence ~ ~

This implies that T is a measure on 9. Since r I p , we can write p = T + ( p - T ) . We claim that p - T is a pure charge. If v is any positive bounded measure on 9 such that v 5j.t -7, then v + T 5 p. Since v + T is a measure, by what we have remarked above, v + T IT. Hence v I0. Since v is positive, v = 0. This shows that p - T is a pure charge. Since, in the Riesz Decomposition Theorem, the decomposition is uniquely achieved, it follows that bc= T. This proves the result. 0

10.3 PURE CHARGES ON U-FIELDS In this section, we obtain further characterizations of pure charges defined on cT-fields. The following theorem implies that any positive bounded pure charge and any positive bounded measure are singular.

10.3.1 Theorem. Let p be a positive bounded charge on a field S o f subsets of a set R. Then EL is a pure charge if and only if for every positive bounded measure h on 9, A in s a n d a > 0, there exists B in 9 s u c h that B c A , A(B)
and

p(A-B)
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THEORY OF CHARGES

Proof. By Theorem 10.1.2, p is a pure charge if and only if p E ca(a, 9)*. Equivalently, p is a pure charge if and only if p A A = 0 for every positive bounded measure A on 9. 0 The above theorem can be strengthened if 9 is a u-field.

10.3.2 Theorem. Let 9 be a u-field of subsets of a set fl and p a positive bounded charge on 9. Then p is a pure charge if and only if for every bounded measure A on $and E > O , there exists B in 9 s u c h that

and

p (B) = 0

A (B')

<E .

Proof. Suppose p is a pure charge. Let A be a positive bounded measure on 9. Let E >O. By Theorem 10.3.1, there exists a set B, in 9 such that p (B,)

< ~ / 2 " and A (BE) < ~ / 2 "

nn2,

B,. Note that B E 9.For every n L 1, p(B) 5 for every n 2 1. Let B = p (B,) < ~ 1 2 " . Consequently, p (B) = 0. Also, A (B') = A (Unzl B:) I CnzlA (B:) IC,,?, ~ / 2 ,= E , as A is countably subadditive. The converse is a consequence of Theorem 10.3.1. Here is another characterization of pure charges on (+-fields useful in constructing examples.

10.3.3 Theorem. Let A be a positive bounded measure on a u-field 9 of subsets of a set a. Let p be a bounded charge on 9 such that p w A,~i.e. p (A)= 0 whenever A E 9 and A (A) = 0. Then p is a pure charge if and only if there exists a decreasing sequence A,, n L 1 of sets in 9 such that A (A,), n L 1 converges to zero and lp [(A:) = 0 for every n L 1.

Proof. The necessity part of this theorem follows from Theorem 10.3.2. To prove the sufficiency part, let (I, be any positive bounded measure on 9 satisfying (I, 5 lp I. From the given hypothesis on p and A, it follows that (I, << A. Let A,, n 2 1 be the given decreasing sequence of sets in 9 such that lim,,,A(A,)=O and lpI(A:)=O for every n r l . Since (I,<
(I,(nnZl

(I,(nnzl

10.4

EXAMPLES

The aim of this section is to construct some interesting examples of pure charges.

10.

245

PURE CHARGES

10.4.1 Example. Let 9 be the Borel c+-field on the real line, R,and let p be a bounded charge on W such that p (B) = 0 for any bounded set B in 9.Then p is a pure charge. (Indeed, if p vanishes for all bounded Borel subsets of R, so does lp 1.) Proof. Let (I, be any positive measure on 9 such that (I, 5 Ip I. Then

Hence (CI = 0. Using the result that any ideal in W is contained in a maximal ideal in 9, one can construct non-trivial charges p of the above type. One simply has to look at the ideal 4 of all bounded Borel subsets of R and then find a maximal ideal in W containing 4. See Section 1.2. It seems impossible to construct a pure charge on a c+-field without taking recourse to some axiom related to the Axiom of Choice.

10.4.2 Example. Let 9 be the field of all clopen subsets of the Cantor set (0, l}Ko. There is no non-zero pure charge on 9.More generally, let 9 be the field of all clopen subsets of a compact Hausdorff space s1. There is no non-zero pure charge on 9.Much more generally, there is no non-zero pure charge on a field 9 of subsets of a set s1 if and only if 9 is a compact A,, = 0 class, i.e. for any decreasing sequence A,,, n 2 1of sets in 9, implies that A,, = 0 for some n 2 1.

n,,

Proof. We will prove the most general statement. If 9 is a compact class, every charge on 9 is a measure. Hence there is no non-zero pure charge If 9 is not a compact class, we can find an infinite sequence A,, on 9. n 2 1 of pairwise disjoint non-empty sets in 9 whose union is R. Let So={A c 0; A is a finite union of sets from {A,,, n 2 1) or A" is a finite union of sets from {A,,,n 2 1)). gois a subfield of 9. On So,let p be defined by p (A) = 0, if A is a finite union of sets from {A,,, n 2 l}, = 1,

otherwise. p is a 0-1 valued charge on Poand is certainly not a measure on go. By Corollary 3.3.5, there is a 0-1 valued charge fi on 9which is an extension of p from go. It is obvious that fi is a non-zero pure charge on 9. 0

10.4.3 Example. Let 9 be a field of subsets of a set R. Any 0-1 valued charge p on 9 is either a pure charge or a measure on 9. Indeed, if (I, is a non-zero measure on 9 satisfying 0 I (I, s p, then p is a measure. 0 10.4.4 Example. Let R = [0, 1) and 9 the field of all sets each of which is a finite disjoint union of sets of the form [ a ,b ) with 0 I a 5 b 5 1. For t

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THEORY OF CHARGES

in (0, 11, define p, on 9 by pr(A) = 1, if there exists a S > 0 such that [t - 8, t ) c A, = 0,

otherwise.

pr is a 0-1 valued charge on $. Since p.r is not a measure, pr is a pure charge. Conversely, if p is any 0-1 valued pure charge on 9, then p = pr for

some t in (0,1]. This can be proved as follows. Since p is a 0-1 valued pure charge, we can find a decreasing sequence A,, n 2 1 of sets in 9 such A, = 0 and p ( A , ) = 1 for every n 2 1. For each n 2 1, we can that findaninterval[a,,b,)cA,suchthatp{[a,,b,)}= land[al, b ~ ) ~ [ ba 2z) ,3 . * . Obviously, [a,, b,) = 0. Let t = a, = b,. Since [a,, b,) = 0, b, = t for some n 2 1. Consequently, p =PI. Now, we obtain explicitly the decomposition of a given positive bounded charge on 9 as a sum of a pure charge and a measure. Let p be any positive bounded charge on 9.Define a real-valued function m on [0, 1) by m ( t )= p{[O,t ) }for 0 5 t < 1. Then m is a monotonically non-decreasing function on [O, 1) and limrpl m(t)
nnzl

-

nn21

nnz,

Since each ptn is a 0-1 valued pure charge, CnZlanpr,is a pure charge. The m function (as defined above for p ) of p -Cnzl anprnis continuous, and consequently, p - C n z l a , p t , is a measure on 9. The above is the desired decomposition of p into a pure charge and a measure. 0

10.5 PURE CHARGES ON BOOLEAN ALGEBRAS The notion of a measure on a field 9 of subsets of a set R is not the same when 9 is viewed as a field of sets and when 9 is viewed as a Boolean algebra. If B is a Boolean algebra and b,, n 2 1 is a sequence of elements in B, Vnzl b, denotes the supremum of {b,, n 2 I}, if it exists. If 9 is a field of sets on a set R, B,, n 2 1 is a sequence of sets in 9 satisfying the B,. If Unzl B, fails to condition that UnzlB, E g,then Vnzl B, = Unal it is possible that Vnzl B, exists in 9 when 9 is viewed as a belong to 9, Boolean algebra. This is the feature that distinguishes the notion of a measure on a field and the notion of a measure on a Boolean algebra. We give an example to amplify this point. Before that, let us formalize the notion of a measure on a Boolean algebra.

10. PURE

CHARGES

247

10.5.1 Definition. Let B be a Boolean algebra or 9 a field of subsets of a set 2 ! viewed as a Boolean algebra. An extended real-valued function p on 9 (or on B) is said to be a measure if for every sequence B,, n L 1 of p(VnrlB n ) = C n r l p(B,) pairwise disjoint sets in 9 with Vnrl B, in 9, holds. The following example demonstrates the difference in the outlook that persists when dealing with measures on fields as well as on Boolean algebras.

10.5.2 Example. Let n={l,2 , 3 , . . . ,a}, and 9, the collection of all finite subsets of {1,2,3,. . .} and their complements. 9 is a field on R. 9 is also a compact class. (See Example 10.4.2.) Consequently, every charge on 9 is a measure. Now, let us view 9 as a Boolean algebra. Consider the following set function p on 9. p ( A )= 0, if A is a finite subset of {1,2, 3, . . .}, = 1, otherwise.

is a charge on 9 but p is not a measure on 9 when 9 is viewed as a Boolean algebra. For, let B, = { n } ,n L 1.B,, n 2 1is a sequence of pairwise disjoint elements in 9 with VnZlB, = R. But p(R) = (Vnrl B,) = 1 and Cn21P(Bn) = 0. p

The decomposition theorem, developed above for a bounded charge defined on a field 9 of subsets of a set 0 as a sum of a pure charge and a measure, takes the following form when 9 is viewed as a Boolean algebra. Can we write p = p l+ p 2 , where p1 is Let p be a bounded charge on 9. a pure charge on 9 and p2 is a measure on 9?We will show subsequently that such a decomposition theorem is possible. Before that, we characterize measures and pure charges on 9 when 9 is viewed as a Boolean algebra.

10.5.3 Theorem. Let %be a field of subsets of a set 0. Let Y be the Stone space of 9, % the field of all clopen subsets of Y, T a n isomorphism from 9to % and Wo the Baire u-field on Y. Let p be a positive bounded charge on 9and b the positive bounded measure on % given by /-z (C) = p (T-'C), C E %. Let 6 be the extension of @ from % to aJ0 as a measure. (See Theorem 3.5.2.) Then the following statements are true. (i). p is a measure on 9when 9is viewed as a Boolean algebra if and only if h ( C ) = O for every nowhere dense closed G s subset C of Y. Equivalently, p is a measure on 9when g i s viewed as a Boolean algebra if and only if fi (D) = 0 for every first category Baire F, set D c Y . (ii). p is a pure charge on 9 when 9is viewed as a Boolean algebra if and only if there is a &st category Baire F, set DOc Y such that 12 (DG)= 0.

Proof. In the argument given below, we view 9 as a Boolean algebra. (i). Let p be a measure on 9. Let C be any nowhere dense closed Gs

248

THEORY OF CHARGES

nn2%

subset of Y. We can write C = C,, where each C, is a clopen subset of Y and C1 1 C 2 x C 3 1.* * . This is possible because in any compact Hausdorff totally disconnected space Y, for any closed set C contained in an open set U, one can find a clopen set V such that C c V c U. Since C is a nowhere dense set, Anrl T - k , = 0 in 9.Since p is a measure on .F, 1 p ( T - C,) = 0. Consequently, limn+m& (C,) = 0. Hence & (C) = 0. The converse can be proved by retracing these steps. (ii). Suppose p is a pure charge on 9. Let r =Sup &(D), where the supremum is taken over all first category Baire F, subsets D of Y. It is obvious that r < a.Let D,, n 2 1 be an increasing sequence of first category Baire F, subsets of Y such that &(D,) = r. Let DO= Un21 D,. Then &(Do)= r and DOis a first category Baire F, subset of Y. Further, Do has the following property. If D is any first category Baire F, subset of Y, then I;. (D -Do) = 0. Let $ on Wo be defined as $ (A)= & (A)- & (A nDo) $ is a measure on 30. Let T be the charge on 9 whose for A in 30. corresponding measure on Wo as explained in the statement of this theorem is the $ given above. If C is a first category Baire F, set, then $(C)= 0. By (i), T is a measure on 9.Since T 5 p and p is a pure charge on 9, T = 0. This shows that for any A in Wo,

&(A)= & (A nDo). Consequently, & (Dg) = 0. For the converse, we proceed as follows. Let p be a charge on 9 such that & (D‘o)= 0 for some first category Baire F, subset Do of Y. Let T be a measure’on 9 such that 0 5 7 s p . By (i), $(C)= 0 for any first category Baire F, subset of Y. In particular, i(Do)=O. Consequently, ;(Y)= $(Do)+?(DG) = 0. Hence T = 0. This shows that p is a pure charge. 0 Now, we give the desired decomposition theorem for charges on Boolean denote the algebras. Let 9 be a field of subsets of a set R. Let Z ( R , 9) collection of all bounded measures on 9 when 9 is viewed as Boolean algebra. Let P(R, 9)denote the collection of all bounded pure charges on 9with 9being viewed as a Boolean algebra. 10.5.4 Theorem. Let 9 be a field of subsets of a set R and p a bounded charge on 9. Then there exists p l in P(R, 9)and p2 in b ( R , 9) such that EL = p t + p z .

Further, this decomposition is unique. Proof. A proof of this theorem can be modelled on the one for Theorem 10.2.1 by establishing that G ( R , 9 ) is a normal vector sublattice of 0 ba(R, 9).

CHAPTER 11

Ranges of Charges

The range of a measure on a cr-field of subsets of a set s1 is a very well understood phenomenon. For example, the range of a real measure p on a cr-field of sets is a closed subset of the real line and further, if p is nonatomic, then its range is an interval. In this chapter, we study ranges of charges. In Section 11.1, we make some general comments on the ranges of bounded charges on fields. In Section 11.2, we show that the range of a bounded charge on a a-field is either a finite set or contains a perfect set. In Section 11.3, we examine the cardinalities of the ranges of charges. In Section 11.4, the validity of Liapounoff’s theorem for strongly continuous charges on fields is examined. In Section 11.5, we construct a positive bounded charge on a field such that its range is neither Lebesgue measurable nor has the property of Baire.

11.1 RANGES OF BOUNDED CHARGES ON FIELDS To begin with, we introduce some basic definitions and establish notation.

11.1.1 Definition. Let p be a charge defined on a field 9 of subsets of a set n. The range of ,u is denoted by R(p) and is defined to be the set

11.1.2 Definition. A charge p defined on a field 9 of subsets of a set s1 is said to be finitely many valued if its range R(p) is a finite set. p is said to be infinitely many valued if R(p) is an infinite set. The range of a finitely many valued charge is easy to describe. For this, we need a lemma.

11.1.3 Lemma. Let p be a finitely many valued real charge defined on a field 9of subsets of a set s1. Then we can find pairwise disjoint sets AI, non-zero real numbers a l , a 2 , . . . , a,, 0-1 valued charges A2,. . . , A, in 9,

250

THEORY OF CHARGES

p1, p2, . . . ,pn on 9 such that pi(Ai) = 1for i = 1,2, . . . ,n and n

p =

C aipi. i=l

Proof. Let R(p) consist of k points. Let

0 = {{BI,Bz, . . . , B,,,}; Bi's are pairwise disjoint, Bi's are in 4, p (Bi)# 0 for every i, and m 2 1). Note that if {B1,B2, . . . , B,}E 0,then m 5 k. Let {Al, AZ,. . . , A,} be a maximal family in 0, i.e. if {B1,B2,. . , ,B,}E 0,then m s n . Each Ai has the following property. If B E 9and B c Ai, then p (B) = 0 or p ( B )= p (Ai). If this is not true, then there is a B in 4 such that B c Ai and p (B) # 0, p(Ai -B) # 0. Then {Al, A2,. . . ,Ai-l, B, Ai -B, A i t l r . ..,A,}€ 0 contradicting the maximality of {Al, Az, . . . ,A,}. Let a i = p(Ai) and p j on 9 be defined by pi(B)= (l/ai)p(Ain B ) for B in 9 and i = 1 , 2 , . . . , n. It Further, is clear that each pi is a 0-1 valued charge on 9. " CL = C aipii=l

For this, use the fact that if B E 9 and B c (A1u A Z U p (B) = 0.

* *

u A,)', then

0

From the above lemma, the following proposition is obvious.

11.1.4 Proposition. Let p be a finitely many valued charge defined on a field 9of subsets of a set 0 having the representation n

1-1. =

C atpi, i=l

where p i ' s are 0-1 valued charges sitting on disjoint sets in 4 and a l , az, . . . ,a, are non-zero real numbers. Then r k

c { l , 2, . . . , n } and 1sk

5n

I

.

Now, we look at infinitely many valued bounded charges defined on fields. We need a preliminary result.

11.1.5 Proposition. If p is any bounded charge defined on a fieId 9 of subsets of a set il and if there is a real number c > O such that Ip(A)I>c whenever A E 9 and p (A)# 0, then p is finitely many valued.

11.

RANGES O F CHARGES

25 1

Proof. We attempt to write p in the form I:=,aipi in the spirit of Lemma 11.1.3. Let SupFEsIp(F)I= k. Since p is bounded, k < 00. Find the largest positive integer N such that Nc 5 k. Let {A, ;a E r}be any family of pairwise disjoint sets in 9 such that p(A,) # 0 for every a in r. We show that r is a finite set and in fact, the cardinality of r is 52N. Suppose the cardinality of r is >2N. Let rl = {a E r; p (A,) > 0 ) and r2= {a E;'I p (A,) < O}. Then, either the cardinality of rl is > N or the cardinality of r2is >N. Assume, without loss of generality, that the cardinality of rl is >N. Select N + 1 distinct sets A,,, A,,, . . . ,A,,+, with a1, a 2 , .. . ,aN+l in rl. Let A = Ami.Then p (A)> ( N + 1)c > k. But p (A) 5 k. This contradiction establishes the claim. As in the proof of Lemma 11.1.3, let

UL'

0 = {{B1, B2, . . . ,B,,,}; Bi's are pairwise disjoint, Bi's are in 9, p (Bi)# 0 for every i, and m L 1). Let {Al, A2, . . . , A,} be any maximal family in 0 with n being the largest possible integer. Following the argument in the proof of Lemma 11.1.3, we can write n

CL =

C i=l

aipi,

where al, a2,. . . ,a, are non-zero real numbers and p l , p 2 , . . . ,p, are 0-1 valued charges on 9sitting on disjoint sets in 9. Hence p is finitely many 0 valued.

As a consequence of the above proposition, we prove the following result which tells us about the nature of R(p) when p is infinitely many valued,

11.1.6 Theorem. Let p be an infinitely many valued bounded charge on a field 9 of subsets of a set R. Then 0 is an accumulation point of R(p). More strongly, R ( p ) is a dense-in-itself set, i.e. R(p) has no isolated points.

Proof. From Proposition 11.1.5, it follows that 0 is an accumulation point of R(p), i.e. in every open interval (-c, c ) with c >0, there exists A in 9 such that p (A) # 0 and p (A)E (-c, c). To prove the second part, let A E 9 be such that p (A) # 0. We show that p (A) is an accumulation point of R(p). Now, we note that either p is infinitely many valued on A or p is infinitely many valued on A". Case (i). p is infinitely many valued on A. By the first part of this theorem, since p is also bounded on A, we can find a sequence B,, n 2 1 in 9such that each B, c A, p (B,) # 0 and limn+cop (B,) = 0. Then p (A-B,) = p (A)- p (B,), n L 1 converges to p (A). Note that p (A - B,) # p (A) for all but a finite number of n's. Hence p(A) is an accumulation point of R(p). Case (ii). p is infinitely many valued on A'. By an argument similar to

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THEORY OF CHARGES

the above, we can find a sequence B,, n r l of sets in 9 such that p (B,) = 0. Note that B, c A', p (B,) f 0 for every n 2 1 and lim,,,p(AuB,)=p(A)+lim,,,p(B,)=p(A). Also, p ( A u B , ) # p ( A ) for all but a finite number of n 's. This shows that p (A) is an accumulation point of R(p). 0 The results established so far can be summed up in the following theorem.

11.1.7 Theorem. Let p be a bounded charge on a field 9of subsets of a set 0. Then either every point of its range R ( p ) is an isolated point in which case R(p) is a finite set or every point of R(p) is an accumulation point of Rb). Now, we take up the case of real charges (not necessarily bounded) defined on fields of sets. Theorems 11.1.6 and 11.1.7 are no longer true for such charges. We present a couple of examples to amplify this point.

11.1.8 Example. Let C! = (1,2 ,3 , . . .}, 9= Finite-cofinite field on C! and p on 9be defined by p ( A ) = #A, = -#A',

if A is finite, if A is cofinite,

where # A denotes the number of points in A. p is a real charge on 9. p is also infinitely many valued. But every point in the range R(,u) = {. . ., -3, -2, -1,O, 1 , 2 , 3 , . ..) is an isolated point of

Rb). 11.1.9 Example. Let C! = ( 0 , 1 , 2 , 3 , . . .}, 9 the finite-cofinite field on 0 and p on 9be defined by

= -p(A"),

if A is cofinite.

(If n = 0, 1+ l / n is interpreted as equal to 1.) p is a real charge on 9 taking infinitely many values. 0 is not an accumulation point of R(p). Note that 1 is an accumulation point of R(p).

11.2 RANGES OF CHARGES ONU-FIELDS Ranges of bounded charges on c+-fieldsexhibit some additional properties over what we have established in the previous section. The main result of

11. RANGES

253

OF CHARGES

this section is that the range of any bounded charge on a u-field is either a finite set or contains a perfect set. We need some preliminary results.

11.2.1 Definition. Let p be a charge defined on a c+-field % of subsets of a set R. Let A,, n z 1 be a sequence of pairwise disjoint sets in a. We say that p is u-additive across A,, n 2 1 if for any B in 8,B c UnzlA,,

F(B)= C PLAnnB) nzl

holds. The following proposition characterizes this notion.

11.2.2, Proposition. Let p be a bounded charge on a a-field 8 of subsets of a set SZ. Let A,, n z 1 be a sequence of pairwise disjoint sets in a. Then the following statements are equivalent. (i). p is u-additive across A,, n z 1. (ii). p + is u-additive across A,, n z 1 an d p - is c+-additive across A,, nzl. (iii). Ip I is u-additive across A,, n 2 1. (iv). I~l(Unz1 An)=Cnzl IpI(An)* (v). Ipl(B,), n z 1 converges to 0, where B, Am,n 2 1.

=urn,,

Proof. (i)+ (ii). Let A E % and A c U n z l A,. We show that p+(A)= C n z l p + ( A n A , ) . Let B E % and B c A . By (i), p(B)=C,,, p ( B n A , ) s C n z lp + ( A nA,). Since this inequality is true for every B in $ with ?I B c A, it follows that p+(A)
+ +

lpl(umzn

C

mzl

IpI(Am)=IpI( mUz l A m ) = I p I (mZ= l Amu mU z n Am)

m=l

m=l

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THEORY OF CHARGES

Hence, equality should prevail throughout, and consequently,

Ip I(B,) =

Cmz, l ~ l ( A ~By) .(iv), it follows that (v)+(i). Let B E % and B c U n Z 1 A , . Then for any n r l , I C m z n p ( B n F(U,,,~,, B AAm) = 0. Hence Am11 5 Ip C IU ,, Am). By (v), P(B)=

C

mzl

W(BnAm).

0

Thus p is u-additive across A,, n I1.

The following proposition gives another property of the above notion. 11.2.3 Proposition. Let p be any charge on a u-field 2l of subsets of a set 0. Let A,, n 2 1 be a sequence of pairwise disjoint sets in 2l such that p is u-additive across A,, n 2 1. Let B,, n r 1 be any sequence of sets in 2l such that B, c A,, for every n 2 1. Then p is u-additive across B,, n 2 1.

0

Proof. This follows directly from Definition 11.2.1.

In the following proposition, for any given bounded charge p which is not finitely many valued, we exhibit a sequence of pairwise disjoint sets across which p is u-additive. 11.2.4 Proposition. Let p be a positive bounded charge on a a-field 2l of subsets of a set a.Suppose the range of p is not finite. Then there exists a sequence W,, n 2 1 of pairwise disjoint sets in % such that p (W,) > 0 for every n I1 and p is u-additive across W,, n 2 1.

Proof. First, we exhibit a sequence Z,, n I1 of pairwise disjoint sets in 8 such that p (Z,) > 0 for every n 2 1. Since R(p) is not a finite set, we can and the range of p on A1 is an find A1 in 2l such that 0 < p (Al) < p (a) infinite set. By similar argument, we can find AZ in %, A 2 c A 1 such that O p (An+l)for every n 2 1.Take Z, = A, - A,+1, n 2 1. Now, we construct the desired sequence W,, n 2 1. Let Y1 = UnzlZ,. Write { 1 , 2 , 3 , . . .) as a disjoint union of two sets N1 and NZ such that both Zn )5 +p(Y 1 )or p(UnENz Zn)5;p(Y1). are infinite. Then either p(UnENl Let YZ= UnEN1 Z, if p (UncNI Z,) 5 +p (Yl), and Yz = UnENz Z, otherwise. Adopting the above procedure for Yz, we can obtain a set Y3 in 2l such that Y 3 c Yz, Y3 is an infinite union of sets from {Z,, n 2 1) and p ( Y 3 ) s i p (YZ). Continuing this procedure, we obtain a sequence Y1 3 YZ3 Y3 3 such that 0 < p (Y,) 5 i p (Yn-l) for every n 2 2 and each Y, is an infinite 9

-

11.

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RANGES OF CHARGES

union of sets from {Z,, n 2 1). It follows that limn+oo p(Y,)=O. Consequently, Y, = 0. Define W, = Y, -YflCl, n ? 1. W,, n z 1 is a sequence of pairwise disjoint sets in %, p (W,) > 0 for every n z 1 and p is a-additive across W,, n z 1 by Proposition 11.2.2.

n,,

The following theorem is the main result of this section.

11.2.5 Theorem. Let p be a bounded charge on a cr-field % of subsets of a set R. Then the range R ( p ) of p is either a finite set or contains a perfect set. Consequently, R(p) is eirher finite or has the power of the continuum.

Proof. Suppose the range of p is not finite. We prove the theorem, first, when p is positive. By Proposition 11.2.4, we can find a sequence W,, n z 1 of painvise disjoint sets in % such that p (W,) > 0 for every n 2 1 and p is cr-additive across W,, n z 1. Then (c,,cp(W,); C c ( l , 2 , 3 , . . .}}c R(p). But {InEC p (W,); C c {1,2,3, . . .}} is a perfect set. Now, let p be any bounded charge on %. Since R(p) is infinite, R(Ip1) is infinite. For, if R(Ip1) is finite, since IpI = p + + p - , then p + takes finitely many values and p - takes finitely many values. Consequently, p = p c - p L takes finitely many values which is a contradiction. Since R(1p I) is infinite, by Proposition 11.2.4, we can find a sequence W,, n 2 1 of pairwise disjoint sets in 8 such that 1p I(W,) > 0 for every n z 1 and IpI is cr-additive across W,, n ? 1. Since lp I(W,) > 0, we can find B, in M such that p (B,) # 0 and B, c W, for every n 2 1. By Propositions 11.2.2 and 11.2.3, p is cr-additive across B,, n z 1. Either we can find an infinite subset N1 c { 1 , 2 , 3 , . . .} such that p(B,) > O for every n EN^ or we can find an infinite subset N Z c { l ,2 , 3 , . . .} such that p(B,)
{xncC

Now, we strengthen the above theorem under the same conditions.

11.2.6 Theorem. Let p be any bounded charge on a a-field % of subsets of a set R. Then either every point in the range R ( p ) of p is an isolated point of R ( p ) in which case p is finitely many valued or every neighbourhood of any point a in R(p) contains a perfect set C c R(p).

Proof. Assume that p is not finitely many valued. For the point 0 E R(p) and the neighbourhood ( - E , E ) with E > 0, we exhibit a perfect set C c R(p) such that C c ( - E , E ) . Since R(1p.I)is infinite, as in the proof of Theorem 11.2.5, we can find a sequence C,, n z 1 of pairwise disjoint sets in % such C,,,), n z 1 converges to that p is cr-additive across C,, n z 1, zero and p(C,) > 0 for all n 2 1 or p(C,) < O for all n 2 1. Ignoring the C,) < E . It follows first few sets if necessary, we can assume that ( pl(Um21

lpl(u,,,

256

THEORY OF CHARGES

that for any subset D c { l , 2 , 3 , . . .}, Ip(UmED Cm)l< E . Thus we find that the perfect set (CmaDp (Cm);D c {1,2,3, . . .}} c ( - E , E ) . Now, let a be a non-zero point in R(p). Let A E % be such that p (A) = a. Suppose p when restricted to A is infinitely many valued. Then, by what we have proved above, for a given E > 0, there exists %' c A n9 such that {p( C ) ;CE %'} is a perfect set contained in (-e, E ) . Note that {p(A-C) = p(A)-p(C); C E ~is} a perfect set contained in ( ~ ( A ) - E~, ( A ) + E ) = (a - E , a + F ) . If, on the other hand, p happens to be finitely many valued on A, then p when restricted to A"is infinitely many valued. By what we have established above, we can find 9 c A'n % such that { p (D); D E 9} is a perfect set contained in (-E, E ) . Now, note that { p (A u D) = p (A)+ p(D); D E ~ is}a perfect set and is contained in &(A)-&,~ ( A ) + E ) = (a - E , a + E ) as well as in R(p). This completes the proof of the theorem. I7

11.3 CARDINALITIES OF RANGES OF CHARGES

In this section, we make some remarks on the cardinalities of ranges of charges. In Section 11.2, we saw that if p is a bounded charge on a v-field of sets, then its range R(p) is either a finite set or has the cardinality of the continuum. If p is a bounded charge on a field 9of sets, then its range R(p) can be of any cardinal number. It is an amusing and instructive exercise for the reader to construct a charge on a suitable field of sets so that its range is of cardinality n, a given integer >1. The following theorem goes beyond finite cardinals. 11.3.1 Theorem. Let K be any infinite cardinal less than or equal to the cardinality of the continuum. Then there is a set R, a field 9 of subsets of R and a real charge p on 9such that the cardinality of the range R(p) of p is K. Proof. Let X be any subset of R having the following properties. (i). Cardinality of X = K. (ii). If x, y E X and a , p are rational numbers, then a x +by E X . Such a set X can be constructed as follows. Let B be any subset of the real line R with cardinality K. Let X = ( ( ~ 1 x +1 a 2 ~ 2+ *

* *

+(Y,x,;

X I ,~

2

. ., . ,X ,

E B,

al, a2,. . .,a , rational numbers and n 2 I},

Then the set X has the above properties (i) and (ii).

11.

257

RANGES OF CHARGES

uy=l

[ai,bi), Take R = R. Let 9 be the collection of all sets A of the form where [al, b l ) , [a2,b2),. . . , [anr6,) are pairwise disjoint intervals, a l 5 b l , a 2 s b Z,..., a , 5 b n , a l , a z , ...,a , E X , 61, b2,..., b , ~ X a n d n r l ,and their complements. 9is clearly a field on R. Define p on 9by n

@(A)=

n

1 (bi- a i ) , i=l

= -@(AC),

p

if A is of the form

u [a;, bi),

i=l

if A' is of the above form.

is a real charge on 9 and R ( p )= X. This shows that R(p) has cardinality

K.

0

11.3.2 Remarks. (i). One can construct a bounded charge p with cardinality of R(p) = tc in Theorem 11.3.1. Further, one could have I.L to be positive as well. (ii). If p is allowed to take infinite values, the construction of a positive charge p with cardinality of its range being a prescribed infinite cardinal number could be made much simpler.

11.4 CHARGES WITH CLOSED RANGE If p is a bounded charge on a field 9 of subsets of a set R, then its range R(p) need not be a closed subset of the real line R. See Theorem 11.3.1. In the following, we give an example of a bounded charge p on a a-field '% of subsets of a set R such that its range R(p) is not a closed set.

11.4.1 Example. Let R = {1,2,3, . . .} and '% = P(R), the class of all subsets of R. Let po be any probability charge on '% such that pO(A) = 0 for any finite subset A of R. For each n r 1, let p, on '% be the measure defined by p,(A)=O, if n EA , = 1,

if n E A and A c R .

Let p =CnrO(1/2,+')pn. Note that $ & R ( p but ) $ is an accumulation point of R ( p ) .Hence R ( p ) is not a closed set. In view of the above example, it is of interest to derive a set of sufficient conditions under which R ( p ) is a closed set. Sobczyk and Hammer Decomposition theorem (See Theorem 5.2.7.) provides a basis for further exploration in this direction. We need a definition, to begin with.

258

THEORY OF CHARGES

11.4.2 Definition. Let 9be a field of subsets of a set fl. A sequence p,,, n L 1 of 0-1 valued charges is said to be discrete if for any given positive integer n, there exists a set A in 8 such that @,(A)= 1 and pm(A)= 0 for every m # n. Let us state a lemma about discrete sequences of charges on fields.

11.4.3 Lemma. If p,,, n L 1 is a discrete sequence of 0-1 valued charges on a field 9 of subsets of a set fl, then there exists a sequence A,, n 2 1 of pairwise disjoint sets in 8 such that p,,(A,) = 1 and p,(A,,) = 0 for all m and n such that m # n. Proof. If B,, n L 1 is a sequence of sets from 9 such that p,(B,) = 1 and p,(B,) = 0 for m # n, then the sequence A,, n 2 1 defined by

u B,,

n-1

A1=B1, and

A, =B,-

n22

m=l

serves the purpose of the lemma. The notion of discreteness introduced above is weaker than the notion of infinite disjointness. See Remark 5.2.3(i). The following is an example amplifying this point. Let f l = { 1 , 2 , 3 , . . . , 00) and 8 the collection of all finite subsets of {1,2,3, . . .} and their complements. On the field 9,for each n 2 1, define pn by @,(A)= 1, if n E A,

=0, ifngA. This sequence p,, n 2 1 of distinct 0-1 valued charges is discrete but not infinitely disjoint. This is because for any countable partition {Fl, Fz, . . .} of R in 9, all but a finite number of sets among {Fl, Fz, . . .} are empty. The following is an instance when the range is a compact set.

11.4.4 Theorem. Let a,,, n L 1 be a sequence of real numbers such that be a a-field of subsets of a set fl and p,,, n 2 1 a discrete sequence of 0- 1 valued charges on 8.Let

Cnzl la,]
p=

C

anpn.

nrl

Then the range R ( p ) of

p

is a compact subset of R and hence is closed.

Proof. By Lemma 11.4.3, we can find a sequence A,, n 1 1 of pairwise disjoint sets in '2l such that p,(A,) = 1 for every n L 1 and pm(A,)= 0 for all m # n. Define a real valued map h on the Cantor set {O,l}Hoby h ( x l ,~

2 , .*)

=

C

nzl

xnan

11.

RANGES OF CHARGES

259

for (xl, XZ, . . .) in (0, l}'". ((0,l)'" is equipped with the usual product topology.) Since Cn2,( a , ( < c ~h, is a continuous function on (0, I}~O. Let D be the range of the function h. Since (0, is a compact space, D is a compact subset of R. Now, we claim that D = R(p). Let a E D . Then there A,,, exists (XI,XZ, . . .) in (0, l}'" such that h(x1, XZ, . . .) = a . Let A = UnEC where C = ( n 2 1; xn = 1). Since % is a cT-field, A E 5%. Further,

= h(x1, x,,

. . .) = a.

Consequently, a E R(p). Conversely, let b f R(p). Then there is a set A in 9l such that p(A) = b = C n z l a,,p,,(A)=Inrl a,p,,(AnA,). Define the sequence x,,, n 2 1 by x,,

= 1,

if p,,(AnA,) = 1,

=0,

if pn(AnA,,)= 0 , n 2 1.

Consequently, ~ ( x I , x. .~.)= ,

C

anxn

n2l

=

C

nr,

aflpfl(AnAn)

=p(A)=beD. This proves that D = R(p).

0

The following result is an analogue of one dimensional Liapounoff's theorem for nonatomic measures on a-fields. See Theorem 5.1.6.

11.4.5 Theorem. Let p be a positive bounded strongly continuous charge defined on a cr-field Vl of subsets of a set a. Then the range R(p) of p is a closed interval. Proof. Let a E (0,@(a)). We show that there exists a set A in 9l such that p(A) = a . Since p is strongly continuous, for E =;, we can find a finite partition of R in such that each set in the partition has p-value <$.Let A1 be the largest possible union of sets from this partition satisfying the Let B1 be any set condition that p (A,) 5 a. Al # R because 0 < a < p (a). in the partition which is not in this union. Then 0 < p (B1)<$and p (A1u B1) > a. If p (A,) = a, the desired claim is established. Suppose p (Al) < a. Since p restricted to B1 is strongly continuous, we can find a finite partition of B1 in 9l such that each set in the partition has p-value<1/22. Let A2 be the largest possible union of sets from this partition such that p (A,) 5 a -p(A1). Since A2# B1, we can find a set BZ from this partition which is

260

THEORY OF CHARGES

not in this union A,. Then 0 < p (Bz)< 1/22 and p (A, u Bz) >a - p (Al), or equivalently, p (Al) p (Az)+ p (B2)> a. If p (A,) = a - p (Al), then Al u A, is the desired set. Otherwise, we proceed to obtain A3 and B3 as above using Bz. If this procedure terminates at a finite stage, we obtain a set A in 3 with p-value equal to a. Otherwise, we get a sequence Al, BI; A,, Bz; . . . of sets in 3 having the following properties for every n 2 1. (i). A , , n B , , = 0 . (ii). A,,+1u B,,+l c B,,. (iii). p (Ad + p (Ad + + p (A,,) 5 a. (iv). pLA1) + F (A,) + * * * +p(An) + p @,)>a. (v). 0 < p (B,) < 1/2". It is now clear that p (A,,) = a . We now show that p(Uflz1 A,,) = CnZlp(A,). Note that

+

---

for every n 2 1. Consequently,

But the inequality

is always true for positive charges. Hence

This proves the result.

0

Now, it is natural to attempt to extend Theorem 11.4.5 to cover the case when we have a general strongly continuous bounded charge on a v-field. We give an example to show that Theorem 11.4.5 fails in general. Before that, we prove a proposition which will be useful in the construction of the desired example.

11.4.6 Proposition. Let p be a bounded charge on a field 9of subsets of a set fl and R(p) its range. Let a = Sup,,~p((B) and p = InfAEsp(A). Then the following statements are equivalent.

11. RANGES

261

OF CHARGES

(i). p admits a H a h n set, i.e. a E-Hahn set for E =O. (See Definition 2.6.1. (ii). a E R(p). (iii). p E R(p). Consequently, R(p) is not a closed set if p does not admit a Hahn set.

Proof. We show that (i) and (ii) are equivalent. (i) 3 (ii). If A is a Hahn set for p , then p (A) = a. (ii) +(i). If A E 9and p (A) = a , then A is a Hahn set for

p.

0

Now, we construct the desired example. In view of Proposition 11.4.6, it suffices to construct a strongly continuous bounded charge on any given infinite u-field not admitting a Hahn set.

11.4.7 Example. Let % be a given infinite cT-field of subsets of a set 0. Let u be any strongly continuous probability charge on a. See Corollary 5.3.3.Using Theorem 11.4.5, we obtain a tree {A61,62 ,...,6,; 81,SZ, . . . ,a, a finite sequence of 0’s and l’s, n 2 1) having the following properties. ....,6,,1= 0 for any n 2 1 and any finite sequence (i). A,,,,, .....6,.0nAS1,62 S1, 82,.. . , S , of 0’s and 1’s. (ii). AS,,^, ....,6,.0uAs,,~, .....6,,1= A61.62....,6, for any n 2 1 and any finite sequence 81, Sz, . . . , S , of 0’s and 1’s. (iii). A o nA, = 0. (iv). A0 u A1= R. and any (v). V(AS1.62....,8 , ) =al(Sl)aZ(S2) * ’ & , ( a n ) for any n sequence 81,SZ,. . . , 8, of 0’s and l’s, where a, (0)= l / ( n + 1)and a , (1)= n / ( n + l ) , n 2 1. Let X = {A E 8 ;v(A) = 0). Look at the quotient Boolean algebra %/Af. For A in [A] denote the equivalence class in % / X containing A. Note .....6,]; S1,Sz, . . . ,a, a sequence of 0’s and l’s, n 2 1) is a tree that {[A6162 in %/X.As in the proof of (ii)+(iii) of Theorem 5.3.2, one can construct a strongly continuous probability charge 7 on 2i/N such that

a,

?([A61,62,....

~ , ] ) = ( Y ~ ( ~ - S ~ ) ( Y Z ( ~’ -* S’ an(l-Sn), Z)

for any finite sequence S1,&, . . . ,S , of 0’s and l’s, and for any n 2 1. Now, define T on 8 by T(A)=?([A]) for A in %. T is a strongly continuous probability charge on % because for any finite sequence S1,Sz, . . . ,a, of 0’s and l’s, 7(A61,62.....~n) 5 l/n, for every n 2 1. v

AT

= 0 because for any n 2 1,

uAs,,s,.___. and uA61,62...., S,*O

where both the unions are taken over all S I , & , .

6

,

~

~

. . , 6, in (0, l), are disjoint

262

THEORY OF CHARGES

a,

with union equal to v-value of the first set and .r-value of the second set are each equal to l / ( n +2). 7 also has the property that if A E 8 and v(A)= 0, then 7(A) = 0. Now, define p on 8 by p = v -7. Since v A T = 0 , p + = v and p - = T. See Theorem 2.2.2(4). It is clear that v and T are distinct and p is a strongly continuous bounded charge on a. We note that p does not,admit a Hahn = 0. set. If p admits a Hahn set A in a, then pf(AC)= v(A') = 0. So, 7(AC) Also, p-(A) = T ( A = ) 0. This implies that T(R)= 0 which is a contradiction. Theorem 11.4.5 says that the range of a positive bounded strongly continuous charge defined on a u-field is convex and closed. The convexity part can be generalized to any finitely many positive bounded strongly continuous charges defined on a c+-field whereas the closedness cannot be generalized.

11.4.8 Example. Let v and T be positive bounded strongly continuous charges on an infinite u-field % as in Example 11.4.7. R(v, T ) = {(.(A), T(A)); A E a} is not a closed set because (1,O)a R(v, T ) but belongs to the closure of R(v, T ) . 11.4.9 Theorem. Let pl,p2, . . . , p,, be positive bounded strongly continuous charges defined on a u-field % of subsets of a set R. Then the range R(~l,~Z,...,~")=~(~l~A)r~z(A),...~~"(A));A~~~Of~

a convex subset of the n-dimensional Euclidean space R". Proof. For n = 1, the result was already established in Theorem 11.4.5. Let us assume the result to be true for n = k and prove the result for n = k + 1. Let p l , pz, . . . ,pk+l be positive bounded strongly continuous charges on a. The proof is divided into several steps as follows. 1". Let ~ ~ = p ~ + p ~ + l - t - . *for * +i p =1 ~ ,+ 2 ~, ..., k + 1 . Then it is easily seen that R(pl, p z , . . . , p k + l ) is convex if and only if R(71, T ~. ., . , T k + 1 ) is convex. So, we prove that R(TI,T ~ . ,. . ,T k + 1 ) is convex. 2". If we show that for every A in a, there exists a set B in % such that B c A and T ~ ( B=)$ T ~ ( for A ) i = 1 , 2 , . . . ,k + 1, then it would follow that R ( T ~T ,~. ., . , 7k+1) is convex. Let us see why. For any given set A in %, by repeated application of the above assertion, for every dyadic rational r between 0 and 1, we can find a set A, with the following properties. (i). A. = 0. (ii). A1 = A. (iii). A, c A, whenever the dyadic rationals r and s satisfy 0 5 r <s I1. (iv). T~(A,) = ~ T ~ for ( A i) = 1,2, . . . ,k + 1 and for any dyadic rational Olrsl.

11.

RANGES OF CHARGES

263

(v). For any real number a between 0 and 1, if we define A, = U A , , where the union is taken over all dyadic rational numbers r 5 a, then A, E fl and T~(A,)= aTi(A)for i = 1 , 2 , . , , , k + 1. Let C, D E %and O 5 a 5 1. Then UTi (C)+ (1 -a)Ti(D) = Ti((C-D)a u (C nD) u (D - C)i-,)

for every i = 1,2, . . . ,k + 1. Using the properties (i), (ii), (iii), (iv) and (v) given above, one can establish the above equality. Consequently, R ( T ~Q, , . . . , Tk+1) is convex. Thus it suffices to exhibit a set B in '%,for a given A in 8, such that B c A and T ~ ( B ) = $ T ~for ( A )every i = 1 , 2 , . . . , k + l . 3". Let C E '% be a set obtained by the induction hypothesis satisfying C c A and T~(C) = $T~(A) for i = 1 , 2 , . . . ,k. If T k + l ( c ) = &k+l(A), then we have finished. If not, let T k + l ( C ) < : T k + l ( A ) < T k + l ( A - C ) . NOW, look at the Sets C,, 0 Ia 5 1 and (A - C),, 0 5 a i 1 obtained as in Step 2" with respect to T I , 7 2 , . . . ,Tk. The existence of these sets is assured by the induction hypothesis. Since T k + l s T k , W e have that Tk+l(Ca- c b ) 5 Tk(Ca- c b ) = (a - b)Tk(C)if a 2 6. Hence Tk+l(C,) is a continuous function of a. Similarly, Tk+l((A-C),) is also a continuous function of a. Hence for O s a 5 1, T k + l ( c a u (A-C)l-,) is a continuous function of a taking the value ? - k + l ( c ) at a = 1 and the value ?-k+l(A-C) at a = 0. Hence there exists a real number a0 in [0, 11 such that ?-k+1(Caou ( A - C L J = $n+l(A). However, for l r i s k , T~(C~U(A-C)~-~)=U~T~(C)+(~-~&~(A-C)

+ (1 - u ~ ) $ T ~ ( A )

=aOh(A) = $ T ~(A).

Thus Ca0u(A-C)l-,=

B serves the purpose.

0

The analogue of Theorem 11.4.9 for bounded strongly continuous charges which are not necessarily positive is also true and is an easy consequence of Theorem 11.4.9.Recall that a bounded charge p is strongly continuous if lp is strongly continuous.

I

11.4.10 Theorem. Let p l , pz,. . . ,pn be a finite number of bounded strongly continuous charges defined on a u-field fl of subsets of a set 0. Then the range R ~ IPZ,, . . . , pn) ={(,UL(A), PZ(A),. . . ,p n ( A ) fA ; = %I of P I , p2, . . . ,p,, is a convex subset of R". Proof. Using the Jordan Decomposition Theorem, write pi = p: - p ; for i = 1,2,. . . ,n. Then all the p:'s and pL;'s are strongly continuous. So, R ( p l, p L, p l, p y, . . . ,p :, p i ) is a convex set by Theorem 11.4.9. From 0 this, it follows easily that R(p1, pz, . . . ,p,,) is convex.

264

THEORY OF CHARGES

11.5 CHARGES WHOSE RANGES ARE NEITHER LEBESGUE MEASURABLE NOR HAVE THE PROPERTY OF BAIRE In this section, we examine whether the range of any probability charge on a a-field is a Borel subset of the real line R. Given any infinite cr-field 8 on a set a,we will exhibit a family of probability charges on 8 the range of each of which is neither Lebesgue measurable nor has the property of Baire. For this purpose, we need some notions and results from Topology and Measure Theory. Let 8 be a a-field of subsets of a set R and 7 a positive measure on 8. The charge space (R, 8,7)is said to be complete if B E 8 whenever B c A for some A in 8 with 7(A) = 0. If (R, %, 7 ) is not complete, we can enlarge 8 so as to make the resultant triplet complete. More precisely, let

& ={B

A A; B c C for some C in 8 with 7(C)= O and A E 8}.

One can show that $l is a cr-field on R and contains %. Define ? on $l by

;(B A A) = 7(A), = 0 and A E 8. F is unambiguously where B c C for some C in 8 with T(C) defined on %, agrees with T on 8 and is indeed a measure on 8.The charge space (R, fl,?) is complete. Sets in 3 are usually called measurable sets. The following is a particularly interesting case of the above. Let 93' be the Borel cr-field on the real line R and A Lebesgue measure on B. Then (R, 93,A ) is not complete. Let 8 be the completion of 9 with respect to A as described above. The sets in 8 are called Lebesgue measurable sets. Obviously, 8 contains the Borel cr-field W properly. Let X be a topological space. Recall that a subset A of X is said to have the property of Buire if there exists an open subset U of X such that A A U is a set of first category. Let W* be the collection of all subsets of X each of which has the property of Baire. Then W*is a cr-field on X and contains the Borel a-field of X, i.e. the smallest cr-field on X containing all open subsets of X. Let X be a complete separable metric space and B its Bore1 o-field. Let XNobe the product space X x X x . . * ={(xl, xz, . ..); x, E X for all n L 1). Let Bmbe the product o-field on XKo,i.e. the smallest a-field on XKocontaining all finite dimensional cylinder sets {Al x AZx * * * x A, x X x X x * * ; A I ,Az,. . . , A , E 9,n 2 1). Let p,, II 2 1 be a sequence of probability measures on BI-Then there exists a unique probability measure p on Bm with the following property.

-

p ( ( A l x A z x . . * x A , x X xX x . . . ) = ~ l ( A l ) p * . 2 ( A 2 ) . . ' ~ n ( A n )

11.

RANGES OF CHARGES

265

for any A I ,A2, . . . ,A, in and n 2 1. p is called the product prot Tbility p,. measure of p,, n 2 1 and is denoted by In the above framework of product spaces, we introduce the followlng notion. A set D c X N o is said to be a tail set if ( y l , y 2 , . . . , Y k , xk+l, X k + Z , . . . ) E D whenever ( X I , X 2 , . . . ,xk, X k + l r X k + z , . . .) E D for some X I , X Z , . . . ,xk in X, for any y l , y 2 , . . . ,Y k in X and for any k 2 1. Now, we state, in this connection, a useful result.

n,,,

Kolmogorov’s 0-1 Law. Let D be a p-measurable tail subset of XHo. T h e n p ( D ) = O o r 1. Now, we look at the space XKoin its product topology, where X is a complete separable metric space. The following result is a topological analogue of the above law.

Oxtoby’s Category Analogue of Kolmogorov’s 0-1 Law. Let D be a tail subset of XKowith the property of Baire. Then either D is of first category or D“ is of first category. Now, we are in a position to construct the desired family of probability charges.

11.5.1 Definition. Let 9 be a field of subsets of a set R and p,, n 2 0 a sequence of 0-1 valued charges on 9. p o is said to be an accumulation point of {p,, n 2 1)if for every A E 9 with p o ( A )= 1,there exists an infinite subset D of {1,2,3, . . .} such that p , ( A ) = 1 for every n E D . The above notion has a simple interpretation in terms of the Stone space Y of 9.Each p n can be identified as a point in Y and the above definition is equivalent to saying that po is an accumulation point of the subset {p,, n 2 1)of Y in the usual topological sense.

11.5.2 Theorem. Let % be a a-field of subsets of a set s2 and p,, n 2 0 be a sequence of 0-1 valued charges on such that p,, n 2 1 is a discrete sequence and p o is an accumulation point of {p,, n 2 1).Define p on % by P=

C

1 p

p

n

-

n 20

Then the range R(p) of p is neither Lebesgue measurable nor has the property of Baire. Proof. Let Z = {0,1} and v the measure on the discrete u-field on Z given ) Let C = ZHoequipped with the product u-field and by v({O})= ~ ( { l=}4. 7 the product probability measure v x v x v . . . on this u-field. Sets in this product u-field are called Bore1 subsets of C . (C is the Cantor set.) Define

266

THEORY OF CHARGES

a real valued function h on C by

hbi,~

.I= nCz l

Xn

2 , .

for ( x l , x z , .. .) in C. This function has many interesting properties. It is one-to-one except for a countable set of points; it is a homeomorphism except for a countable set of points; h(A) is a Borel subset of [0,1] if and only if A is Borel subset of C; h preserves the measures 7 and the Lebesgue measure A on [0, 11, i.e. 7(hP1(B))= A (B) for every Borel subset B of [0,1]; h(A) is a Lebesgue measurable subset of [0,1] if and only if A is a 7-measurable subset of C; h(A) has the property of Baire in [0, 11 if and only if A has the property of Baire in C. See Kuratowski (1966). In view of these properties of h, if we show that F = {(@*(A), p1(A),pz(A), . . .); A E?l} is neither 7-measurable nor has the property of Baire in C , then it will follow that R(p) is neither Lebesgue measurable nor has the property of Baire in [0,1]. This is because h(F)= N P 1. Let D = {(pl(A),p2(A), . . .); A E8,pO(A)= 1). So, if we show that D is neither 7-measurable nor has the property of Baire in C, the desired conclusion about F follows. First, we show that D is not 7-measurable. We prove that D is a tail set. Since pn, n 2 1 is a discrete sequence, by Lemma 11.4.3, we can find a sequence A,, a 2 1 of pairwise disjoint sets in 8 such that p,(A,) = 1 for every n L 1and p,,,(A,) = 0 for all rn # n. Since pois an accumulation point of {p,,, n 2 I}, po is distinct from all p,,, n 2 1. One can assume, without = 0 for every n 2 1. This follows from the loss of generality, that pO(An) fact that if 6 and 7 are two distinct 0-1 valued charges on 91, then there is a set A in 8 such that e(A)=O=q(AC).Let (x1,x2,.. .)= (pi(A),pZ(A),. . . ) E D for some A in ?l with pO(A)= 1. Let k be any positive integer and y1, y 2 , . . . ,Yk be any finite sequence of 0’s and 1’s. Let E l = { l ~ i ~ k ; y i = O }and E Z = { l ~ i ~ k ; y i = l } .Let B = (A-UIEEI Ai)u (UIEE2 A;). It is obvious that pO(B)= 1, pl(B) = yl, Pz(B) = Yz, . . . pk(B) = Ykt Pk+i(B)= @k+l(A), P k + z ( B ) = pk+Z(A),, . . Consequently, (yl, y2, . . . ,yk, &+I, &+2, . . .) E D. Hence D is a tail set. Suppose D is 7-measurable. By the Kolmogorov’s 0-1 law, T(D)= 0 or 1. Let us look at the map 4 from C to C defined by 4(x1, x 2 , . . .) = (1-xl, 1-xz, . . .) for (xl,xz, . . .) in C. We claim that 4(D)nD = 0 and $ ( D ) u D = C . Suppose $ ( D ) n D # 0 . Let (xI,x2,.. . ) ~ l j l ( D ) n DThen . we can find two sets A and B in ?l such that po(A)= 1= pO(B)and 9

(xi, XZ, . . .>= (pi(A),FAA), . . .I,

(1-xi, 1- X Z , . . .) = (pi(B), pz(B),

.I.

11.

RANGES OF CHARGES

267

Note that p o ( A n B ) = 1 and ( p l ( A n B ) , p z ( A n B), . . .) = (0’0, . . .). This is a contradiction to the fact that po is an accumulation point of {p,,,n L l}. Therefore, +(D) nD = 0. To show that 4(D) u D = C, let (xl, x2,. . .) E C . Let E = {n 2 1;x,, = 1) and A = UnEE A,,. Then (pl(A), pZ(A),. . .) = (x1,x2,.. .). If p o ( A ) = 1, then (x1,x2,.. . ) E D . If pdA)=O, then (xl,x2, . . .) E $(D). This shows that 4(D) u D = C. Note that t,b preserves = T(G) for every 7-measurable set G contained the measure 7 , i.e. ~((tr(G)) = 1, then T(~(D)) = 1 and consequently, 7(C) = 2 which in C. Now, if T(D) = 0, then T ( $ ( D ) )= 0 which is again a contradicis a contradiction. If T(D) tion since it works out that T(C)= 0. Thus D is not 7-measurable. To prove that D does not have the property of Baire, one can repeat the above argument and use Oxtoby’s category analogue of Kolmogorov’s 0 0-1 law and Baire Category theorem.

11.5.3 Remark. If 3 is an infinite u-field on a set R, one can always find a sequence p,,, IZ 2 0 of 0-1 valued charges on satisfying the conditions imposed in Theorem 11.5.2.

CHAPTER 12

On Lifting

The purpose of this chapter is to present some ideas on lifting in the setting of charges on fields. In the following, we elucidate the concept of lifting. For the Let 9 be a field of subsets of a set R and 9 an ideal in 9. following definition, recall the definition of the quotient Boolean algebra 919 and the natural homomorphism h from 9 to 919 which takes each (See Section 1.4.) set A in 9to its equivalence class [A] in 9.

12.1 Definition. The natural homomorphism h from 9 to 919 is said to admit a fifting if there exists a subfield Poof 9 such that the map h restricted to Sois an isomorphism from to 9/9. A lifting is tantamount to selecting one set from each equivalence class of 9 so that the resulting collection of sets becomes a field on Q and is isomorphic to 919.This notion of lifting can be reformulated as follows. Suppose the natural homomorphism h from 9 to 9/9admits a lifting. Let II, be the induced isomorphism from 919 to 90.

z

949/9

90.

Let p be the composition of h and II,, i.e., p = II, h. Then this map p has the following properties. (i). p is a homomophism from 9to 9. (ii). p is onto Po. (iii). If A, B E 9 and A B, then p (A) = p (B). (iv). A p (A) for every A in 9. For ease of expression, we call p the lifting of 9 with respect to the ideal 9. If n={l,2 , 3 , . . .}, 9=9’(R) and 4 the. ideal of all finite subsets of Q, it is not difficult to see that 9does not admit a lifting with respect to 9. A well-known result of von Neumann and Maharam establishes the existence of a lifting in the case when (Q,@,p) is a complete measure space, i.e. 9is a c+-field of subsets of R, p is a positive bounded measure on 9 with the property that B E 9 whenever B c A, A E 9 and p (A) = 0, and 9 ={A E 9; p (A) = 0 ) the ideal of all sets in 9with p-measure zero. See Maharam (1958). 0

-

-

12.

269

O N LIFI'ING

It is natural to enquire about the existence of a lifting of 9with respect to 9 in the above if we assume p to be a charge only. But lifting fails to exist in the generality mentioned above and the following theorem due to Maharam-Erdos amplifies this point. (Recall the notion of a density charge from Example 2.1.3(10).)

12.2 Theorem. Let a={1,2,3, . . .}, 9= P(a)and p any density charge on 9. Let 9 = {A E 9; p (A) = 0). Then there is no lifting of 9with respect to the ideal 9. Proof. The proof is carried out in the following steps. 1". Suppose there exists a lifting p of 9with respect to 9. 2". Let 1< p l < p 2 < . * be a sequence of positive integers such that pi and pi are mutually prime for every i # j and Cizl l/pi < 00. It follows that this sequence has the following properties. (i) lim,,m n / p , = 0. (ii) (1- l / p i ) converges (to a non-zero real number). 3". F o r l s j s p i a n d i = 1 , 2 , 3,..., let

nizl

A i j = { j j, + p i , j + 2 p i , . . .}.

Note that, for each i r 1, Ail,A i 2 , .. . , Aipiare pairwise disjoint sets with union R. So, p (Ai1),p (Ai2),. . . ,p (Aipi) are pairwise disjoint sets with union R. Let Ri be the set among {p(Ail),p(Ai2),. . . ,p(Aipz)} containing i and denote the corresponding set Aii by Si for each i = 1 , 2 , 3 , . . .. 4". Obviously, p ( S i )= Ri = 0. Since Si) contains S j for every j 2 1, it follows that p ( u i z l S i ) =a. 5". Let Ti be the set obtained from Si by removing the first element of Si, i r 1.LetT* =UizlTi. Sincep(T*)~p(Ti)=p(Si)foreveryjL1,itfollows that p(T*) =a. This implies, by the definition of lifting, that T* si, i.e. p (T*) = 1 . We show that

uizl

uirl

p(uizl

-uizl

which will then lead to a contradiction. 6". We use the notation # A for the number of elements in A. Let Let r be a positive integer such that

1 1 -<&I6

i and -<&I6 i>rpi Pi Let ko be a positive integer such that ko)p1p2*

foreveryilr.

2' p r and - < ~ / 6 . ko

E

> 0.

270

THEORY OF CHARGES

We show that for any integer k > ko,

(Since p is a density charge on 9, we will then have #T* n { l , 2 , . . . , k } p(T*)= lim

k

k-fw

= 1 - n (1-;).I is1

7". Let k > ko be fixed. Let s be the smallest integer i such that pi > k, i.e. r. Note that every element in Ti is greater than pi. If j' 2 s, then pi 2 p s . Consequently, Tj n {1,2, . . . ,k } = 0 if j 2 s. It suffices to estimate # (Us:: Ti)n{1,2, . . . , k } . 8". First, we estimate # T i ) n { l ,2,. . . , k } . Here, we introduce the following notation; for any two numbers u and 6, a = 6 means la - b I 5 1. By the inclusion-exclusion principle, ps-l 5 k

(ulzl r

n { l , 2 ,..., k } =

C # T i n { 1 , 2,..., k }

i=l

r

r

- Ci = l j C= l # T i n T j n { l , 2 , . . . , k } i <j I

I

I

+I C C # T i n T j n T u n { 1 , 2 ,. . . , k } - * * . j=l u = l j = l

i<j
+(- l ) ' - ' # T 1 n T Z n . . . n T r n { l , 2 , . . . , k } .

Since Ti is of the form {ri +pi, ri +2pS . . .} for some 15 ri
k Tin{1,2, . . . , k } = -

Pi

for every i B 1. We now show that, for i # j ,

+

Ti nTi c {rij +pipi, rij 2pipj,rij + 3pipj, . . .} for some 15 rij
#Ti nTi n { l , 2 , . . . ,k}---. PiPi

12.

27 1

ON LIFTING

Pursuing this argument, we obtain

r

r

k

r

-1 1 1 -+*.*+(-1)' PiPiPU

i = l i=l u = l

P1P2 '

* *

Pr

i<j
n{1,2,

. . . ,k}-k

lr+(~)+...+(:)=2'-1<2'. 9". Using the same argument as above, we note that k #TiA{1,2, ..., k } l l + Pi for every r + 1s j 5 s - 1. 10". Thus, finally, we have

1

#T*n{1,2,. k

. . ,k}-

k

[' #

UielTi n { l , 2 , . . . , k} )k

2' < - + ~ / 3 + ( - +s - 1 k k

1 -), 1

i>rP;

by 8", 6" and 9" respectively. s-1

< ~ / 6 ~+ / +-+ 3

~ / 6

Ps-1

< ~ / 6 4+ 3 -k ~ / 6 ~+ / 6 E<. This completes the proof.

(1-3)

APPENDIX 1

Notes and Comments

CHAPTER 1 Sections 1.2, 1.3 and 1.4 offer fairly standard, though cursory, treatment of the topics covered. For set theoretical notions dealt in Section 1.2, one could refer to Kamke (1950) or Kelley (1955) or Dunford and Schwartz (1954) for more details. Kelley (1955) is a standard reference for topological concepts covered in Section 1.3. Halmos (1963) and Sikorski (1969) are excellent sources for ideas on Boolean Algebras. Some parts of Section 1.1 may be found in Halmos (1950). Theorem 1.1.9(1) is due to Pettis (1951). Corollary 1.1.12 is inspired by Section 4 of Sikorski (1969). A substantial part of Section 1.5 on Functional Analytic concepts is inspired by the fundamental paper of Bochner and Phillips (1941).

CHAPTER 2 Bochner and Phillips (1941) identify the space ba(R, S)of all bounded of charges on the field 9 of subsets of the set R with the space ca(R’, 9’) all bounded measures on a suitable cr-field 9’of subsets of a suitable set R‘. From this it follows that ba(R, 9)is a boundedly complete vector lattice. Theorem 2.2.1 arrives at the same conclusion more directly using a bank of ideas from vector lattices. Construction of invariant charges using Banach limits is a standard practice in Ergodic Theory. See Example 2.1.3(8). We have used Banach limits to show the existence of Density charges. See Example 2.1.3(10). The comprehensive Jordan Decomposition Theorem proved in Section 2.5 is new. Existence of &-HahnDecomposition for charges for every E > 0 was first established by Darst ( 1 9 6 2 ~ ) . Topsae (1979) gave some conditions under which a charge becomes a measure. This result is a generalization of Theorem 2.3.4. First, we need a definition.

APPENDIX

1

273

Definition. A collection % of subsets of a set R is called a monocompact class if it has the following property: if C,, n 2 1 is a decreasing sequence of sets in % with C, = 0,then there exists m 2 1 such that C, = 0.

n,,,

Theorem A.l. Let 9be a field of subsets of a set R and % a monocompact class of subsets of R. Let p be a positive bounded charge on 9having the following approximation property: for any F in B a n d E > 0 there exist C in % and G in 9such that G c C c F and p (F- G )< E . Then p is a measure on S. Christensen (1971) gave some conditions under which a charge becomes a measure. We present some of his results. Let 9 be a a-field of subsets of a set R. For v in ca(R, S),let h, be the map on .F defined by

h,(F) = v(F),

F E9.

Let % be the smallest a-field on 9with respect to which each of the maps h , is measurable for v in ca(R, 9).

Theorem A.2. Let p be a real charge on 9, If p is measurable with respect to the a-field % on 9, i.e.

h i ' (B) = {FE9; p(F) E B}E % for every Borel subset B of the real line R, then p is a measure on 9. Another result in the context of Polish spaces, i.e. complete separable metric spaces, can be described as follows. Let R be a Polish space and 9 its Borel a-field, i.e. the smallest a-field on R containing all open subsets of R. Let p be a probability charge on 9. Let R* be the collection of all closed subsets of R. The gist of the following result is that if p restricted to R* is a decent function on R", then p is a measure on 9. We now elaborate this statement. We can introduce a suitable metric d" on St" so that (a*,d " ) becomes a separable metric space. Let d be a metric on R compatible with its topology. Since R is separable, one can always choose d to be a precompact metric on R. Define a metric d* on R* by d * ( A , B) =Sup {max { d ( a ,B), d ( A , b)}},

A, B E R".

aeA beB

Then

(a*,d * ) is a separable metric space. Let 9"be the Borel a-field on

R*. Theorem A.3. If the map p restricted to R* is measurable with respect to 9*, then p is a measure on 9.

274

THEORY OF CHARGES

Rao (1971) gave a sufficient condition under which a charge becomes a measure. Let p be a positive real charge defined on a field 9 of subsets of a set SZ. A subfield goof 9is said to be p-pure if the following conditions are met. (i). p (AN)= 0 for some N L 1 wheneve; A,, n L 1 is a sequence in 90 satisfying Al 3 A2 3 A3 3 . . and A, = 0. (ii) p(A)=Inf(C,,,p(A,); { A f l , n Z 1 } c 9 o and U n ~ l A , ~ Aforl every A in 9. (This condition means that the Caratheodory measure induced by p on gocoincides with p on 9.)

-

n,,

Theorem A.4. If there exists a p-pure subfield 90 of 9, then p is a measure on 9. Rao (1971) stated that the converse of the above theorem is true. This is not correct, however, as the folIowing discussion demonstrates.

Theorem AS. Let 9 be a a-field of subsets Q f a set s2 and p a nonatomic probability measure on 9. Let 90be a p-pure subfield of 9 and 91the smallest u-field on SZ containing 90. Then p is nonatomic on 9 1 . (For the definition of a nonatomic measure, see Chapter 5.) Proof. Obviously, 9 1 c 9. We show that 9 and g1are p-equivalent, i.e. given A in 9 there exists B in slsuch that p (A A B) = 0. To begin with, given E > 0 we show that there exists a set B, in g1such that p (A A B) < E . Since 90is a p-pure subfield of 9, there exists a sequence En,n 2 1 in 90 such that UnZlE, 3 A and Cnzl p(E,) < p (A) + E . Clearly, UnZl E, E gl. Take B, =UnzlEn. Thus for each n 2 1, we can find B, in sl such that B,. Since A A (lim p ( A A B,) < 1/2". Take B = Iim B,) c lim sup,,oo (A A B,) and p (lim sup,+m (A A B,)) = 0 (Borel-Cantelli Lemma), it follows that p ( A A B) = 0. Finally, since 9 and 9 1 are pequivalent, p is nonatomic on S1. 0 Theorem A.6. Let 9be a a-field of subsets of a set s2 and p a nonatomic probability measure on 9. Let g o be a p-pure subfield of 9.Then p is strongly continuous on 90. Proof. This is a consequence of Theorem A5 above and Proposition 5.3.7. Theorem A.7. Let 9 be a a-field of subsets of a set SZ and p a nonatomic probability measure on 9. Let 90 be a p-pure subfield of 9. Then there exists a set A in 9of cardinality greater than or equal to the cardinality of the coniinuum c such that p (A) = 0.

Proof. By Theorem A6, p is a strongly continuous probability charge on 90. So, there exist two sets Bo and B1 in .F0 such that Bo n B 1 = 0 , O < p (Bo) < 1/1(2) and O
APPENDIX

1

275

p0300)<1/2(2*),O < l / n (2”) for all il , iz, . . . ,in,in+lin (0, 1) and n 2 1. For each n 5 1, let A,, = Bil,i2 ....,in, where the union is taken over all il, iz, . . . , i, in (0,l). It is obvious that p (A,,) < l / n for every n z 1. Let A,,. It now follows that p(A) = 0. Since 9,is,a p-pure subfield A= of 9, it follows that Bil.iz,..., # 0 for any sequence i l , i 2 , . . . of 0’s and 1’s. (Actually, here, we use the fact that gosatisfies (i) on p. 274 and that Bil,i2,...,in’~ satisfy (iii) above.) Consequently, the cardinality of A L c.

u

n,,,,

n,,,,

Sierpiiiski showed with the aid of continuum hypothesis the existence of a set R, a cr-field 9 on R and a nonatomic probability measure p on 9 such that p (A) = 0 if and only if A is at most countable. In this case, in of 9. For a discussion view of Theorem A7, there is no p-pure subfield 90 on the above type of measure, see Marczewski (1953,7(iv), p. 123). In fact, continuum hypothesis is not needed at all for an example. Any non-compact measure on a countably generated cr-field would serve the purpose. See Bhaskara Rao, Bhaskara Rao and Rao (1982) and Frolik and Pachl (1973). Theorems A.l, A.2, A.3 and A.4 stated above are analogous to Proposition 2.3.2 and Theorem 2.3.4 in spirit.

CHAPTER 3 The results of Sections 3.1 and 3.2 are due to Tarski (1938) and Horn and Tarski (1948). Our treatment is slightly different from the one given in Horn and Tarski (1948). The results of Section 3.3 are due to Los and Marczewski (1949). Section 3.4 contains some ideas of Los and Marczewski (1949) in its development. Some of the results of Section 3.5 are due to Pettis (1951). For the results of Section 3.6, see Guy and Maharam (1972). Extending some of the results of this chapter to group-valued charges, Bhaskara Rao and Aversa (1982) have proved the following theorem.

Theorem A.8. Let G be an algebraically compact abelian group. If p is any G-valued charge defined on a subfield %’ of a field 9 of subsets of a set R, then there is a G-valued charge fi on 9 which extends p. Carlson and Prikry (1982) have proved that the above result is true for all groups using a result on Specker groups. For Specker groups see Fuchs (1970).

276

THEORY OF CHARGES

CHAPTER 4 The notion of a.e. [ p ] introduced in Definition 4.2.4 is slightly different from the standard one adopted in Measure Theory. For example, we say f s g a.e. [ p ] if there exists a null function h such that f s g + h . The definition prevalent in Measure Theory is that f s g a.e. [ p ] if and only if JpI*({wE R ; f ( w f > g ( w ) } ) = O . Of course, if IpI*({w ER; f ( w ) > g ( w ) } ) = O , then f s g a.e. [ p ] according to Definition 4.2.4 though the converse is not true. If a D-integrable function f has the property that D

I

f d p 2 0 for every E in 9,

E

thenf? 0 a.e. [ p ] in the sense of Definition 4.2.4 but Ipl*({w E R;f(w)
Example. Let R = {1,2,3, . . . , co}, 9 ={A c R; A or A' is a finite subset of { 1 , 2 , 3 , . . .}} and p on 9be defined by A is finite, p ( A ) = 0 if A E 9, = 1 otherwise. Let % be the smallest c+-fieldon R containing 9. Indeed, % = P(R). Let @ be the extension of p from 9 to % as a measure. In fact, for A c R, @(A)=1 if c o ~ A , =O

ifco&A.

APPENDIX

1

277

It can be observed that Ll(s1, 9, p ) and L ~ ( f la, , C;) are both complete but Ll(s1, 9,p ) f Llfs1, 8,C;). For, obviously, rim)€ Li(s1, a, @) but I { m ) a L1(sl, 9, p ) . (Observe that is not T2-measurable in the framework of

(a,9, @).I CHAPTER 5 The main decomposition theorem presented in Section 5.2 is due to . results in this chapter are due to Sobczyk and Hammer ( 1 9 4 4 ~ )Other the authors (1973) and (1978).It is possible to derive Theorem 5.2.7 using Riesz Decomposition Theorem on vector lattices. See Section 1.5.

CHAPTER 6 The treatment of absolute continuity, singularity and Lebesgue Decomposition Theorem given here follows closely that of Bochner and Phillips (1941).Darst (1962a),(1962b)and (1963) has worked extensively on extensions of Lebesgue Decomposition Theorem in the unbounded case. The following are some of his results.

Theorem A.9. Let p and u be two charges on a field 9of subsets of a set s1 such that one of p and u is bounded. Then u admits a Lebesgue Decomposition with respect to p if and only if there exists a sequence E,, n 2 1 of decreasing sets in 9 s u c h that Ip [(E,) = 0 and lim,,m IuI(E;) isfinite.

A special case of this theorem is the following result. Theorem A.lO. Let p and u be tw5 charges on a field 9of subsets of a set s1 such that u is bounded. Then u admits a Lebesgue Decomposition with respect to p. The Radon-Nikodym Theorem presented here was originally formulated and proved by Bochner (1939). Later, it was proved again by various people at various times: Bochner and Phillips (1941),Dunford and Schwartz (1964), Fefferman (1967), Darst and Green (1968), Dubins (1969), Darst (19706)and Pachl(l972). The proof presented here is due to Pachl(l972). This proof, even though it looks lengthy, is elementary and in our opinion, the simplest. Another proof of Radon-Nikodym theorem appears in Chapter 7 as a simple consequence of a result on V1 spaces. This proof is due to Bochner and Phillips (1941). Maynard (1979) gave necessary and sufficient conditions for the existence of exact Radon-Nikodym derivatives.

278

THEORY OF CHARGES

Dunford and Schwartz (1964) use Stone Representation Theorem for Boolean algebras in their proof of Radon-Nikodym theorem.

CHAPTER 7 V,-spaces were introduced by Bochner (1939). Leader (1953) studied these spaces in great detail. Our presentation follows closely that of Leader (1953) with simplifications. Remark 7.5.2 follows from Fefferman (1968) and Bhaskara Rao and Halevy (1977). In the later paper, the results on V,-spaces were obtained using Stone Representation Theorem on Boolean Algebras. Green (1970/71) gave necessary and sufficient conditions for the comp ) for a given charge space (R, 9,p ) . pleteness, in particular, of 21(R, 9, Let 9, p ) be a probability charge space. For A, B in 9, say A - B if p (A A B) = 0. is an equivalence relation. Let 9*be the collection of all equivalence classes of 9. 9*is a Boolean Algebra. Let R‘ be the Stone 9’the class of all clopen subsets of R‘ and 3’the Bore1 space of 9*, cr-field on R’. There is a natural probability measure p ’ on 3’which corresponds to the probability charge p on 9via the correspondences

(a,

-

9+ 9” f* 9’3’. Green’s necessary and sufficient conditions for the completeness of

LZ1(R,9, p ) are that R‘ be extremely disconnected (i.e. the closure of every open subset of R’ is open) and every open subset of R’ is equivalent to its closure under p ’ . These conditions are not correct. An example can be constructed from the following theorem of Bhaskara Rao and Aversa (1982).

Theorem A . l l . Let p be a positive bounded measure on a field 9of subsets of a set R. Let % be the smallest a-field on R containing 9 and fi the positive bounded measure on 2l which extends p. Then

2 l ( R , 9, p )=21(R,

%9

6)

if for any E > 0 and for any A in 2l there exist B and C in 9such that B c A c C a n d p(C-B)<€. This theorem gives the following two examples.

Example 1. Let R be any set and 9be the finite-cofinite field on R. Then for any positive bounded measure p on S,2?l(R, 9, p ) is complete.

APPENDIX

1

279

Example 2. Let 9 be the field generated by all the open subsets of the g 1 ( R , 9, p) real line R. Then for any positive bounded measure p on 9, is complete.

CHAPTER 8

With the exceptions of Sections 8.5 and 8.6, the treatment presented here follows that of Phillips (1940a), Darst (1966), Seever (1968), Porcelli (1960), Brooks and Jewett (1970) and Leader (1953). In Sections 8.5 and 8.6, we have included theresultsof Bell (1979). The proof of Phillips’Lemma presented here is essentially the original proof of Phillips (1940a). The results on Nikodym theorem and Vitali-Hahn-Saks theorem use essentially the ideas of Seever (1968). We now make some observations on Theorem 8.7.3 which gives equivalent conditions for weak convergence. Condition (ii) is due to Hildebrandt (1934). Condition (iii) is due to Porcelli (1960) The proof of (iv)J(v) is due to Darst (1966). Condition (v) is due to Leader (1953). The results on weak convergence in ba(fk, F)are scatteed in the literature and we made an attempt to bring some semblance of order by unifying them in our Theorem 8.7.3. Some equivalent conditions in Theorem 8.7.3 and quite a few results in this chapter are new.

CHAPTER 9

The basic ideas in the development of refinement integrals are due to Kolmogoroff (1930). The main result (Theorem 9.2.1) in Section 9.2 is due to Keisler (1979). Our proof of this result is slightly different from the one presented by Keisler (1979) in that, we avoid using a deep result in refinement integrals due to Kolmogoroff. CHAPTER 10

The decomposition theorem presented in Section 10.2 is due to Yosida and Hewitt (1952) (and Kakutani, as Yosida and Hewitt mention). Their original proof is a working-out of the proof of Riesz Decomposition

280

THEORY OF CHARGES

a.

Theorem for the vector lattice ba(R, 9)and the normal sublattice ca(R, Some alternative proofs, extensions and generalizations of this decomposition theorem can also be found in the literature. See Ranga Rao (1958), Plachky (1971), Traynor (1972) and Huff (1973). Pure charges on Boolean algebras are characterized by Lloyd (1963). See Theorem 10.5.3.

CHAPTER 11 A substantial part of these results is from a paper of K. P. S. Bhaskara Rao (1981). Theorem 11.2.5 is due to Sobczyk and Hammer (19446, Theorem 3.3, p. 849) when p is nonnegative. They gave an example of a bounded charge on a a-field of subsets of a set R whose range is countably infinite, thus negating the validity of their Theorem 3.3 for general bounded charges on a-fields. See Sobczyk and Hammer (19446, Theorem 3.4, p. 850). This example is incorrect. Their Theorem 3.3 is true for any bounded charge. See Theorem 11.2.5.See also K. P. S. Bhaskara Rao (1981). Here is an amusing example of a real charge whose range is the set of all rational numbers. Let R = {1,2,3, . . .}, 9 the finite-cofinite field on R and p on 9 is defined by p(N=

c n1 -3

if A is finite,

neA

= - I -,n1

if A is cofinite, A c R.

noAc

The range R ( p ) of p is the set of all rational numbers. This follows from the Egyptian Fraction Theorem in Number Theory, that, every positive k l/nj, where n l , n z , . . . , n k are rational number can be written as distinct positive integers. We now give an example of a bounded charge p taking positive and negative values such that 0 is not a two-sided accumulation point of R (p ). Let R = {1,2,3, . . .}, 9the finite-cofinite field on R and p on 9is defined by 1 if A is finite, F (A) = -YA2R) = 1 - p (A'),

if A is cofinite.

is a bounded charge on 9 and 0 is not a two-sided accumulation point of R h ) . p

APPENDIX

1

281

Theorem 11.4.5 is due to Sobczyk and Hammer (1944a, Theorem 5.1, p. 843). It was also rediscovered by Maharam (1976, Theorem 2, p. 49). According to Theorem 11.4.4, if p,,, n 2 1 is a discrete sequence of 0-1 valued charges on a cT-field % of subsets of a set n, then the range R ( p ) of p (1/2")p,, is compact. Erdos (see Maharam (1976) posed the problem of whether the range R(p) of p =CnZl (1/2,,)p, is a non-Bore1 set when {pl, p 2 , . . .} is not a discrete set. The answer to this question is affirmative in some special cases as pointed out in Theorem 11.5.2. If the answer to the Erdos' problem is in the affirmative whenever {p,,: n L 1) is a dense-in-itself subset of the Stone space Y of %, then the answer for the general case is also in the affirmative. In connection with the above problem, we establish the following assertions of Maharam (1976). Let p,,, n 2 1be a sequence of 0-1 valued charges on a c+-field %. Assume that {p,, :n I1) is a dense-in-itself subset of the Stone space Y of 8. (a) If {(pl(A), p2(A), . . .): A E %} is a 7-measurable subset of (0, l}Ko, then it has .r-measure zero. (For the definition of 7 see the proof of Theorem 11.5.2.) (b) If {(pl(A), p2(A), . . .): A E has the property of Baire, then it is of first category. (1/2")p,,. If R ( p ) (a) and (b) can be interpreted as follows. Let p =Inzl is Lebesgue measurable, then it has Lebesgue measure zero. If R ( p ) has the property of Baire, then it is of first category. (a) can be established as follows. The set E = {(pl(A),pZ(A),. . .): A E %} is a subgroup of the abelian group C = {0,1}"" under coordinate addition modulo 2, and is disjoint with the set {(XI,x2, . . .) E C: xi = 0 for all but a finite number of 2s). Now, if E is 7-measurable and T(E)>0, then F = E + E = { ( x 1 + y 1 , x 2 + y 2 , . . .):(x1,x2,. . . ) E E and (y1,y2,. . .)EE} should contain a point of {(xl, x2, . . .) E C: xi = 0 for all but a finite number of i's}. See Oxtoby (1971) and Bhaskara Rao and Bhaskara Rao (1974). But F = E. This contradiction proves (a). In Theorem 11.5.2, the proof that D is not 7-measurable is essentially due to Sierpinski (1938).

CHAPTER 12 The main result of this chapter is from Maharam (1976). See also Weissacker (1982) and Talagrand (1981) for further related results.

APPENDIX 2

Selected Annotated Bibliography BOOKS To begin with, we give a list of books we have consulted at one time or the other in our study of finitely additive measures.

1. BIRKHOFF, G. “Lattice Theory” American Mathematical Society Colloquium Publications, New York, 1948. 2. DUBINS, L. E. and SAVAGE, L. J. “How to Gamble If You Must (Inequalities for Stochastic Processes)”. McGraw-Hill, London, 1965. 3. DUNFORD, N. and SCHWARTZ, J. T. “Linear Operators, Part I: General Theory”. Wiley-Interscience, London, 1954. 4. FUCHS, L. “Infinite Abelian Groups,” Vol. 1. Academic Press, London and New York, 1970. 5 . HALMOS, P. R. “Measure Theory”. Van Nostrand, London, 1950.

6. HALMOS, P. R. “Lectures on Boolean Algebras”. Van Nostrand, London, 1963. 7. KAMKE, E. “Theory of Sets”. Dover Publications, New York, 1950.

8. KELLEY, J. L. “General Topology”. Van Nostrand, London, 1955. 9. KURATOWSKI, K. “Topology”, Vol. 1. Academic Press, London and New York, 1966. 10. OXTOBY, J. C. “Measure and Category”. Springer-Verlag, New York, 1971.

11. PFANZAGL, J. and PIERLO, W. “Compact Systems of Sets”, Lecture Notes in Mathematics No. 16. Springer-Verlag, New York, 1966. 12. SCHAEFER, H. H. “Banach Lattices and Positive Operators”. SpringerVerlag, New York, 1974.

13. SIKORSKI, R. “BooIean Algebras”, Third Edition. Springer-Verlag, New York, 1969.

PAPERS We now give a list of research papers which we have come across in our quest to achieve a good understanding of the world of finitely additive measures. This list

APPENDIX 2

283

is by no means exhaustive on this subject. We provide a brief description of some of the salient features of some of the papers which we think are relevant to the main theme of this book. Most of the papers contain a lot more information than the cursory annotation we provide here. ALBANO, L. (1974). Teoremi di decompozione per funzioni finitamente additive in un reticolo relativamente complementato, Ricerche Mat. 23, 63-86. Lebesgue, Jordan, Yosida-Hewitt Decomposition theorems are discussed for charges taking values in a complete vector lattice. ALEKSANDROV, I. I. (1973).The decomposition of a finitely additive set function (in Russian), Comment. Math. Univ. Carolinae 14, 87-93. Using results on vector lattices, Lebesgue Decomposition theorem for charges is proved. See Section 6.2. ALIC, M. and KRONFELD, B. (1969). A remark on finitely additive measures, Glasnik Mat., Ser. III 4(24), 197-200. The problem of embedding a charge space into a measure space is considered. See also Fefferman (1968). ANDO, T. (1961). Convergent sequences of finitely additive measures, Pacific J. Math. 11, 395-404. Vitali-Hahn-Saks theorem for sequences of charges defined on u-fields is proved. See Chapter 8. ARMSTRONG, T. and PRIKRY, K. (1978). Residual measures, Illinois J. Math.

22, 64-78. ARMSTRONG, T. and PRIKRY, K. (1981).Liapounoff’s theorem for non-atomic finitely-additive, finite-dimensional vector-valued measures, Trans. Amer. Math. SOC.266,499-514. We came across this paper at the proof-reading stage of this book. Ranges of charges defined on fields of sets is the main theme of this paper. See Chapter 11. There is some overlap of results between this paper and that of Bhaskara Rao (1981). ARMSTRONG, T. and PRIKRY, K. (1982). On the semimetric of a Boolean algebra induced by a finitely additive probability measure, Pacific J. Math. 99,

249-263.

Let p be a probability charge on a field 9 of subsets of a set n and N, the ideal of all p-null sets. On the quotient Boolean algebra 9/NW, there is a natural metric d, defined by d,([A], [B]) = p (AAB) for [A], [B] in 9/N,. The d,) is studied in detail in this paper. completion of the metric space (9/NW, See also Bhaskara Rao and Bhaskara Rao (1977). AUSTIN, D. G. (1955).An isomorphism for finitely additive measures, Proc. Amer. Math. SOC.6, 205-208. An isomorphism theorem for charge spaces analogous to the classical Halmos and von Neumann (1942) theorem for measure spaces is proved. See also Buck and Buck (1947) for a similar result.

284

THEORY OF CHARGES

BANACH, S. (1948).On measures in independent fields, StudiaMath. 10,159-177. Let (R,.9,,,EL,), a E r be a collection of probability charge spaces in which each p, is a probability measure. Let 9 be the field on R generated by is,, CY E r}.A common extension of all these probability measures to 9 as a probability measure with a special property is sought. See also Marczewski (1951). BARONE, E. (1978). Sulle misure sernplicimenten additive non continue, Atti Sem. Mat. Fix Univ. Modena 27, 39-44. An example of a nonatomic charge which is not strongly nonatomic is given. BARONE, E. and BHASKARA RAO, K. P. S. (1981). Misure di probabilita finitamente additive e continue invarianti per transforrnazioni, Boll. Un. Mat. Ital. 18, 175-184. Existence of a nonatornic probability charge invariant with respect to a transformation is discussed. BARONE, E. and BHASKARA RAO, K. P. S. (1981). PoincarC recurrence theorem for finitely additive measures, Rendiconti di Matematica 1, 521-526. The classical PoincarC recurrence theorem in Ergodic theory is discussed in the context of a charge space. BARONE, E., GIANNONE, A. and SCOZZAFAVA, R. (1980). On some aspects of the theory and applications of finitely additive probability measures, Pubbl. Istit. Mat. A p p l . Fac. Univ. Stud. Roma Quaderno 16, 43-53. Sobczyk-Hammer Decomposition theorem for charges on w-fields is proved. See Section 5.2. BAUER, H. (1955). Darstellung additiver Funktionen auf Booleschen Algebren als Mengenfunktionen, Archiv der Math. 6, 215-222. Let B* be a Boolean algebra and B a subalgebra of B*. The notion of a positive bounded charge on B being a measure relative to B* is introduced and some of the results of Yosida and Hewitt (1952) and Hewitt (1953),are generalized. BELL, W. C. (1977). A decomposition of additive set functions, Pacific J. Math. 72,305-311. Every positive bounded charge p on a field 9 of subsets of a set R can be written as a sum of positive bounded charges p l and p zon 9with the following properties. (i) p 1 and hzare mutually singular. (ii) The linear functional induced by the Lebesgue Decomposition of charges with respect to p I has a refinement integral representation. See Chapter 9. BELL, W. C. (1979).Unbounded uniformly absolutely continuous sets of measures, Proc. Amer. Math. SOC.71, 58-62. A uniformly absolutely continuous set of charges can be decomposed into bounded and finite dimensional parts. See Section 8.6. BELL, W. C. (1979). Hellinger integrals and set function derivatives, Houston J. Math. 5, 465-481.

APPENDIX 2

285

Using the concept of a refinement integral (see Chapter 9), the author introduces the notion of derivative of a bounded charge on a field 9 of sets with respect to a real valued function on 9and studies some of its properties. BELL, W. C. (1981). Approximate Hahn decompositions, uniform absolute continuity and uniform integrability, J. Math. Anal. Appl., 80, 393-405. A sequence p,,, n 2 1 of bounded charges on a field B of subsets of a set R is said to be disjoint if IpnlA (pml= 0 for all n # m. A subset G of ba(R,B) is uniformly absolutely continuous if and-only if each disjoint sequence in (&)+ is norm convergent to zero, where (G)’ is the set of positive elements in 6 = {q E baW, 9); Iq I < Ipl for some p in G}. See Theorem 8.7.7 for a related result. BELL, W. C. and KEISLER, M. (1979). A characterization of the representable Lebesgue Decomposition Projections, Pacific J. Math. 84, 185-186. Representability of the linear functional induced by the Lebesgue Decomposition of charges with respect to a fixed charge is studied. BHASKARA RAO, K. P. S. (1981). Remarks on ranges of charges, to appear in Illinois J. Math. See Chapter 11 and Armstrong and Prikry (1981). See also Notes and Comments on Chapter 11. BHASKARA RAO, K. P. S. and AVERSA, V. (1982). On Tarski’s extension theorem for group valued charges, a pre-print. See Notes and Comments on Chapter 3. See also Carlson and Prikry (1982). BHASKARA RAO, K. P. S. and AVERSA, V. (1982). A remark on E. Green’s paper “Completeness of L,-spaces over finitely additive set functions”, to appear in Coll. Math. See Notes and Comments on Chapter 7. BHASKARA RAO, K. P. S. and BHASKARA RAO, M. (1973). Charges on Boolean algebras and almost discrete spaces, Mathematika 20, 214-223. A systematic study of nonatomic, strongly continuous and strongly nonatomic charges is made. Superatomic Boolean algebras are characterized. See Chapter 5. BHASKARA RAO, K. P. S. and BHASKARA RAO, M. (1974). A category analogue of the Hewitt-Savage zero-one law, Proc. Amer. Math. SOC.44, 497-499. See Notes and Comments on Chapter 11. BHASKARA RAO, K. P. S. and BHASKARA RAO, M. (1977). Topological properties of charge algebras, Rev. Roum. Math. Pures et A p p l . 22, 363-375. Let p be a positive bounded charge on a field 9 of subsets of a set R. p induces a natural semi-metric or pseudo-metric d, on 9by d,(A, B) = p (AAB) for A, B in 9. This paper studies some topological properties of the semi-metric space (9,d,). See also Armstrong and Prikry (1982). BHASKARA RAO K. P. S. and BHASKARA RAO, M. (1978). Existence of nonatomic charges, J. Austral. Math. SOC.25 (Series A), 1-6.

286

THEORY O F CHARGES

A set of necessary and sufficient conditions for the existence of a nonatomic charge on a given Boolean algebra is provided. See Chapter 5. BHASKARA RAO, K. P. S. and BHASKARA RAO, M. (1981).On the separating number of a finite family of charges, Math. Nuchr. 101, 215-217. Given any finite number of distinct charges on a field 9 of subsets of a set R, a partition of R in 9 with minimal number of sets is sought which separates the charges. BHASKARA RAO, K. P. S., BHASKARA RAO, M. and RAO, B. V. (1982). A note on ,u-pure sub-fields, a pre-print. Let p be a probability measure on a countably generated u-field of subsets of a set 0. The following are equivalent. (i) There exists a p-pure sub-field of 9. (ii) p is perfect. (iii) p is compact. For the notions of compactness and perfectness of measures, see Ryll-Nardzewski (1953). This result was anticipated by Frolik and Pachl (1973). See also Notes and Comments on Chapter ‘ I

L.

BHASKARA RAO, M. and HALEVY, A. (1977). On Leader’s V,-spaces of finitely additive measures, J. Reine Angew. Math. 2931294, 204-216. V,-spaces (Leader (1953)) are shown to be isometrically isomorphic to L,spaces of a measure space using the Stone Representation Theorem for Boolean algebras. See Notes and Comments on Chapter 7. BOCHNER, S. (1939).Additive set functions on groups, Ann. Math. 40,769-799. V,-spaces (1s p 5 a)in the setting of charges are introduced. Radon-Nikodym theorem for charges is also proved. See Chapters 7 and 6. See also Notes and Comments on Chapters 6 and 7. BOCHNER, S. (1940). FiniteIy additive integral, Ann. Math. 41,495-504. Representation of positive linear functionals on vector lattices is provided. BOCHNER, S. (1946). Finitely additive set functions and stochastic processes, Proc. Nut. Acad. Sci., U.S.A. 32,259-261. This paper introduces a notion called stochastic phenomenon. Let P be a probability measure on a u-field ? ofIsubsets of a set S and 9 a field of subsets of a set R. A real valued function f defined on 9 x S is called a stochastic phenomenon if f(ul=, Ei, - ) = f ( E , . ) a.e. [PI for every finite number of pairwise disjoint sets El, E2,.. . , E, in 9. A stochastic phenomenon can be regarded as a general type of stochastic process and it includes many known processes. BOCHNER, S. and PHILLIPS, R. S. (1941). Additive set functions and vector lattices, Ann. Math. 42, 316-324. This is a fundamental paper on vector lattices. Riesz Decomposition Theorem in the general setting of vector lattices is proved. See Section 1.5. Lebesgue Decomposition Theorem in the setting of charges is observed. See Section 6.2. BOeDAN, V. and OBERE, R. A. (1978). Topological rings of sets and the theory of vector measures, Dissert. Math. 154. Nikodym and Vitali-Hahn-Saks type of theorems for finitely additive vector

APPENDIX 2

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measures on rings of sets are presented along the lines initiated by Drewnowski (1972a, b, c). BROOKS, J. K. (1969). On the Vitali-Hahn-Saks and Nikodym theorems, Proc. Nut. Acad. Sci., U.S.A. 64,468-471. Simplified proofs of Vitali-Hahn-Saks and Nikodym theorems for measures on cr-fields are presented. BROOKS, J. K. (1972). Weak compactness in the space of vector measures, Bull. Amer. Math. SOC., 78, 284-287. A set of necessary and sufficient conditions are given for a subset of ba(R, 9‘) to be conditionally weakly compact in a general setting. BROOKS, J. K. (1973).Equicontinuity, Absolute continuity and weak compactness in Measure Theory, a paper in “Vector and Operator valued Measures and Applications”, (D. H. Tucker and H. B. Maynard, eds). pp. 51-61. Academic Press, London and New York. Some extensions of the result in Brooks (1972) are dealt with. BROOKS, J. K. (1974).Interchange of limit theorems for finitely additive measures, Rev. Roumaine Math. Pures et A p p l . 19, 731-744. Let 9 be a field of subsets of a set R and 9*the smallest u-field on R containing 9. Let K c ba(fl, 9*). Equivalence of uniform s-boundedness of K over 9*and uniform s-boundedness of K over 9is examined. See also Brooks and Dinculeanu (1974). BROOKS, J. K. and DINCULEANU, N. (1974). Strong additivity, absolute continuity and compactness in spaces of measures, J. Math. Anal. A p p l . 45, 156-1 7 5. The notion of strong additivity of a charge studied in this paper is the same as s-boundedness we have used in this book. See Definition 2.1.4. Uniform s-boundedness of a collection of bounded charges is characterized in terms of uniform absolute continuity. See Theorem 8.7.7 for another characterization of uniform absolute continuity of a sequence of charges. BROOKS, J. K. and JEWETT, R. S. (1970). On finitely additive vector measures, Proc. Nut. Acad. Sci., U.S.A.61, 1294-1298. Vitali-Hahn-Saks and Nikodym theorems for charges on cT-fields are proved. BUCK, R. C. (1946). The measure theoretic approach to density, Arner. J. Math. 68,560-580. Density charges are constructed from simple set functions defined on a particular class of subsets of { l , 2 , 3 , . . . }. See Section 2.1. BUCK, E. F. and BUCK, R. C. (1947). A note on finitely additive measures, Amer. J. Math. 69,413-420. Isomorphism of the charge spaces (R, 9, F ) and (R’, 9:,m*), where R’= { 1 , 2 , 3 , . , . }, 9; contains all arithmetic progressions and m” is a density-like charge on 9:,is investigated.

288

THEORY OF CHARGES

BUMBY, R. and ELLENTUCK, E. (1969). Finitely additive measures and the first digit problem, Fund. Math. 65, 33-42. A class S of probability charges on the power set of the set of all natural numbers is constructed such that for any p in S, p (P,) = log,, ( n + l),where P, is the set of all natural numbers whose first significant digit lies between 1 andn,lsns9. CANDELORO, D. and SACCHETTI, A. M. (1978). Su alcuni problemi relativi a misura scalari sub additive e applicazionial caso dell’additivita finita, Atti. Sem. Mat. Fis. Uniu. Modena 27,284-296. Connectedness of the range of a bounded charge is studied. CARLSON, T. and PRIKRY, K. (1982). Ranges of Signed Measures, a pre-print. Theorem A.8 is true for all abelian groups. See Notes and Comments on Chapter 3. This paper came to our notice at the proofreading stage of this book. CHENEY, C. A. and de KORVIN, A . (1976/77). The representation of linear operators on spaces of finitely additive set functions, Proc. Edinburgh Math. SOC.2(20), 233-242. An integral (Kolmogorov-Burkill type) representation of a continuous linear operator from V,(R, 9, p ) to a Banach space is provided. See also Edwards and Wayment (1974). CHERSI, F. (1978). Finitely additive invariant measures, Boll. Un. Mat. Ital. A(5) 15, 176-179. Existence of invariant probability charges is shown. See Section 2.1. CHRISTENSEN, J. P. R. (1971). Borel structures and a topological zero-one law, Math. Scand. 29, 245-255. A probability charge p on the Borel c+-field of a complete separable metric space X is a measure if p is measurable as a function on the space of all closed subsets of X equipped with a natural distance (metric) function. See Notes and Comments on Chapter 2. COBZAS, S. (1976). Hahn Decompositions of finitely additive measures, Arch. Math. 27, 620-621. Let 9 be a field of subsets of a set R. Let ba(R,9) and % ( R , F ) be as in Sections 2.2 and 4.7 respectively. ba(R, 9) is equipped with the total variation norm and %(a, 9)is equipped with the supremum norm. ba(R, 9)is the dual In this paper, it is proved that a p in b a ( R , 9 ) admits an exact of %(R, 9). Hahn decomposition if and only if p attains its norm on the unit ball of %‘(a, 9). DARST, R. B. (1961). A note on abstract integration, Trans. Amer. Math. SOC. 99,292-297. A real valued function on a set R is 9-continuous if and only iff is integrable where 9 is a field on R. See with respect to every bounded charge on 9, Section 4.7. See also Leader (1955).

APPENDIX 2

289

DARST, R. B. (1962a). A decomposition of finitely additive set functions, J. Reine Angew. Math. 210, 31-37. Lebesgue Decomposition Theorem for bounded charges is proved. See Section 6.2. DARST, R. B. (1962b). A decomposition for complete normed abelian groups with applications to spaces of additive set functions, Trans. Amer. Math. SOC. 103,549-558. A Lebesgue type decomposition theorem is proved in a general setting. Validity of Lebesgue Decomposition Theorem for unbounded charges is examined. See Section 6.2. See also Notes and Comments on Chapter 6. DARST, R. B. (1963). The Lebesgue Decomposition, Duke Math. J. 30,553-556. An extension of a result in Darst (1962b) is established. DARST, R. B. (1966). A direct proof of Porcelli’s condition for weak convergence, Proc. Amer. Math. SOC.17, 1094-1096. See Section 8.7 and Notes and Comments on Chapter 8. DARST, R. B. (1967). On a theorem of Nikodym with applications to weak convergence and von Neumann algebras, Pacific J. Math. 23, 473-477. Nikodym theorem for sequences of charges on a a-field is proved. See Section 8.4. DARST, R. B. (1970a). The Vitali-Hahn-Saks and Nikodym theorems for additive set functions, Bull. Amer. Math. SOC. 76, 1297-1298. Vitali-Hahn-Saks and Nikodym theorems are proved for charges on a-fields. See Sections 8.4 and 8.8. DARST, R. B. (1970b). The Lebesgue Decomposition, Radon-Nikodym derivative, conditional expectation and martingale convergence for lattice of sets, Pacific J. Math. 35, 581-600. The Lebesgue Decomposition Theorem and the Radon-Nikodym theorem are considered in a general setting. DARST, R. B. and GREEN, E. (1968). On a Radon-Nikodym theorem for finitely additive set functions, Pacific J. Math. 27, 255-259. Radon-Nikodym theorem for finitely additive bounded complex valued functions on a field of sets is proved. See Fefferman (1967). See also Notes and Comments on Chapter 6. DIESTEL, J. and UHL, J. J. Jr. (1977). Vector measures, American Mathematical Society Math. Surveys 15, Providence. A sharper version of Phillips’ lemma due to Rosenthal is presented. DREWNOWSKI, L. (1972a). Topological rings of sets, continuous set functions, integration I, Bull. Acad. Polon. Sci., Ser. Sci. Math. Astronom. Phys. 20, 269-276. Rings equipped with a topology such that the operations A and fl become continuous are presented. Vitali-Hahn-Saks theorem for charges taking values in a topological group is proved.

290

THEORY OF CHARGES

DREWNOWSKI, L. (1972b). Topological rings of sets, continuous set functions, integration 11, Bull. Acad. Polon. Sci., Ser. Sci. Math. Astronom. Phys. 20, 277-286. This is a continuation of the paper of Drewnowski (1972a) in which extensions of s-bounded group-valued charges on a ring of sets to the a-ring generated by the ring are sought. DREWNOWSKI, L. (1972~).Topological rings of sets, continuous set functions, integration 111, Bull. Acad. Polon. Sci., Ser. Sci. Math. Astronom. Phys. 20, 439-445. Nikodym theorem for group-valued measures is proved. DREWNOWSKI, L. (1972d). Equivalence of Brooks-Jewett, Vitali-Hahn-Saks and Nikodym Theorems, Bull. Acad. Polon. Sci., Ser. Sci. Math. Astronom. Phys. 20, 725-731. See the following paper of Drewnowski (1973). DREWNOWSKI, L. (1973). Decomposition of set functions, Studia Math., 48, 23-48. This paper and the above paper give analogues of Vitali-Hahn-Saks and Nikodym theorems for sequences of strongly bounded charges defined on o-rings of sets taking values in a commutative Hausdorff topological group. DREWNOWSKI, L. (1973a). Uniform boundedness principle for finitely additive vector measures, Bull. Acad. Polon. Sci., Ser. Sci. Math. Astronom. Phys. 21, 115-118. Nikodym theorem for s-bounded charges on a o-ring of sets taking values in a normed group is proved. DOLGUSEV, A. N. (1981). Remark on finitely additive measures, Sibirsk. Mat. 2 . 2 2 , 105-120. DUBINS, L. E. (1969). An elementary proof of Bochner’s finitely additive RadonNikodym Theorem. Amer. Math. Monthly 76, 520-523. See Notes and Comments on Chapter 6. EDWARDS, J. R. and WAYMENT, S. G. (1971). Representations for transforma154 251-265. tions continuous in the BV norm, Trans. Amer. Math. SOC. An integral representation theorem for continuous linear functionals on V,(Q 9, p ) , where a =[0,1], can be deduced using v-integrals. EDWARDS, J. R. and WAYMENT, S . G. (1974). Extensions of the v-integral, Trans. Amer. Math. SOC.191, 165-184. An integral (with respect to a charge) representation of continuous linear p ) into a Banach space can be deduced. See also Cheney operators on V,(Q 9, and de Korvin (1976/77). FAIRES, B. F. (1970). On Vitali-Hahn-Saks-Nikodym type theorems, Ann. Insti. Fourier, Grenoble 26, No. 4, 99-114. Vitali-Hahn-Saks and Nikodym type theorems are studied in the setting of

APPENDIX 2

291

Boolean algebras with interpolation property (which are same as Boolean algebras with Seever property) for Banach-space-valued s-bounded charges. See Seever (1968) and Chapter 8. FEFFERMAN, C. (1967). A Radon-Nikodym theorem for finitely additive set functions, Pacific J. Math. 23, 35-45. Radon-Nikodym theorem for bounded complex valued charges on a field of sets is proved. See also Darst and Green (1968). FEFFERMAN, C. (1968). L,-spaces over finitely additive measures, Pacific J. Math. 26, 265-271. The problem of embedding a charge space into a measure space is considered. See also AliC and Kronfeld (1969). de FINETTI, B. (1955). La Struttura delle Distribuzioni in un insieme astratto qualsiasi, Giorn. Ist. Ital. Attuari 18, 15-28. A decomposition theorem similar to the one given by Sobczyk and Hammer (1944) is proved. FROLIK, Z. and PACHL, J. (1973). Pure measures, Comment. Math. Uniu. Carolinae 14, 279-293. Properties of charges p which admit p-pure subfields of 9 are studied. Pure measures discussed here are different from pure charges studied in Chapter 10. This paper pointed out an error in M. M. Rao's (1971) paper. See Bhaskara Rao, Bhaskara Rao and Rao (1982) and also Notes and Comments on Chapter 2. GAIFMAN, H. (1964). Concerning measures on Boolean algebras, Pacific J. Math. 14,61-73. Existence of a strictly positive charge on a field 9 of subsets of a set R is related to some conditions in Set Theory. Most importantly, he exhibited a Boolean algebra satisfying countable chain condition having no strictly positive charge on it. See also Kelley (1959). GOULD, G. G. (1965). Integration over vector-valued measures, Proc. London Math. SOC.15, 193-225. Integration of scalar-valued functions with respect to vector-valued charges is developed. See Section 4.5. GRECO, G. H. (1981). The continuous measures defined on a Boolean algebra (Italian), A n n . Univ. Ferrara Ser. VII(N.S.)26, 213-218. A characterization of superatomic Boolean algebras B in terms of exact Hahn Decomposition of bounded charges on B is provided. GREEN, E. (1970/71). Completeness of L,-spaces over finitely additive set functions, Coll. Math. 22, 257-261. See Notes and Comments on Chapter 7. See also Bhaskara Rao and Aversa (1982).

292

THEORY OF CHARGES

GUY, D. L. (1961). Common extensions of finitely additive probability measures, Portugal. Math. 20, 1-5. A necessary and sufficient condition is given for the existence of a common extension of two probability charges defined on two different fields on the same set to any field containing these two fields as a probability charge. See Section 3.6. HALMOS, P. R. (1947). The set of values of a finite measure, Buff.Amer. Math. SOC. 53, 138-141. A simple proof of a result of Liapounoff on the range of a measure is given. HALMOS, P. R. (1948). The range of a vector measure, Bull. Amer. Math. Soc.

54,416-421. A simple proof of two results of Liapounoff on the range of a measure with values in a finite dimensional vector space is provided. HALMOS, P. R. and von NEUMANN, J. (1942). Operator methods in classical mechanics 11, Ann. Math. 43, 332-350. Isomorphism between two measure spaces is abstractly characterized. HATTA, L. and WAYMENT, S. G. (1973). A Radon-Nikodym theorem for the v-integral, J. Reine Angew. Math. 259, 137-146. An analogue of the classical Radon-Nikodym theorem is considered in the setting of v-integrals for charges. an der HEIDEN, U. (1978). On the representatation of linear functionals by finitely additive set functions, Arch. Math. 30, 210-214. Necessary and sufficient conditions for the existence of a charge p for a given linear functional on a Stonean lattice of functions to be expressed as an integral with respect to p are derived. HEWITT, E. (1951). A problem concerning finitely additive measures, Mat. Tidsskr. B 81-94. The structure of all bounded charges on the field 9 on Q = [0, 1) generated by all intervals of the type [a, b ) with 0 5 a I b 5 1 is determined. See Section

10.4. HEWITT, E. (1953). A note on measures on Boolean algebras, Duke Math. J. 20,

25 3-25 6. Distinction between measures on fields and measures on Boolean algebras is pointed out. See Section 10.5. HILDEBRANDT, T. H. (1934). On bounded linear functional operations, Trans. 36,868-875. Amer. Math. SOC. The dual of the Banach space of all 9-continuous functions is shown to be ba(Q, 9-),where 9is a field on Q. See Section 4.7. HILDEBRANDT, T. H. (1938). Linear operations of functions of bounded variation, Bull. Amer. Math. SOC.44, 75.

APPENDIX 2

293

Integral representation of continuous linear functionals on a subspace of is given, where R = [0, 11. ba(R, 9) HILDEBRANDT, T. H. (1940). On unconditional convergence in normed vector spaces, Bull. Amer. Math. SOC.46, 959-962. Properties of unconditional convergence in normed linear spaces are used to define some simple measures on P(R), where R = {1,2,3, . . . }. HILDEBRANDT, T. H. (1958). On a theorem in the space el of absolutely convergent sequences with applications to completely additive set functions, Math. Research Center Report No. 62 Madison, Wisconsin. HODGES, J. L. Jr. and HORN, A. (1948). On Maharam’s conditions for measure, Trans. Amer. Math. SOC.64, 594-595. One of the conditions in the set of necessary and sufficient conditions given by Maharam (1947) for a Boolean c+-algebrato admit a strictly positive bounded measure is shown to be redundant. HORN, A. and TARSKI, A. (1948). Measures on Boolean algebras, Trans. Amer. Math. SOC.64, 467497. Extension of set functions defined on a collection Y? of subsets of a set R to a field 9 on R containing %? as charges are sought. See Chapter 3. See also Notes and Comments on Chapter 3. HUFF, R. E. (1973). The Yosida-Hewitt Decomposition as an Ergodic theorem, a paper in “Vector and Operator Valued Measures And Applications”, (D. H. Tucker and H. B. Maynard, eds), pp. 133-139. Academic Press, London and New York. The Yosida-Hewitt (1952) Decomposition of a charge as a sum of a pure charge and a measure is obtained using an ergodic theorem for commutative semigroup of idempotent linear operators on a Banach space. This approach covers both the scalar valued and vector valued charges. JECH, T. and PRIKRY, K. (1979). On projections of finitely additive measures, Proc. Amer. Math. SOC.74, 161-165. There exists a translation invariant charge p on P(R), where R = {1,2,3, . . . } and a function f from R to R such that p = pf-’ and p (A)5 ; iff is one-to-one on A c R . JORSBOE, 0. G. (1966). Set transformations and Invariant measures, A Survey, Math. Inst. Aarhus Universitet Various Publications Series, No. 3, Aarhus, Denmark. Invariant charges are constructed using Banach limits. See Section 2.1. KEISLER, M. (1979). Integral representation for elements of the dual of ba(9, Z), Pacific J. Math. 83, 177-183. If 9is a superatomic Boolean algebra, then every continuous linear functional on ba(R, 5)has a refinement integral representation. See Chapter 9. See also Notes and Comments on Chapter 9.

294

THEORY OF CHARGES

KELLEY, J. L. (1959). Measures on Boolean algebras, Pacific J. Math. 9, 11651177. Necessary and suficient conditions for a Boolean algebra to admit a strictly positive charge are given. KELLEY, J. L. and SRINIVASAN, T. P. (1970/71). Pre-measures on lattices of sets, Math. Ann. 190, 233-241. Necessary and sufficient conditions are given for a positive bounded charge defined on a lattice of sets closed under countable intersections admits an extension as a measure to the cr-field generated by the lattice. KELLEY, J. L., NAYAK, M. K. and SRINIVASAN, T. P. (1973). Pre-measures on lattice of sets 11. “Proceedings of a Symposium on Vector and Operator valued measures and Applications” held at University of Utah, August 7-12, 1972, (D. H. Tucker and H. B. Maynard, eds) Academic Press, London and New York. Some improvements of the results of Kelley and Srinivasan (1970/71) are presented. KHURANA, S. S. (1978).A note on Radon-Nikodym theorem for finitely additive measures, Pacific J. Math. 74, 103-104. Radon-Nikodym theorem for charges is proved using the corresponding result for measures. The argument is essentially that of Dunford and Schwartz (1954), p. 315. KINGMAN, J. F. C. (1967). Additive set functions and the theory of probability, Proc. Camb. Phil. SOC.63, 767-775. A certain notion dense subset of a set fl in the context of a field of subsets of fl is introduced and its ramifications are studied. KISYNSKI, J. (1968). Remark on strongly additive set functions, Fund. Math. 63, 3 2 7-332. Smiley’s (1944) result on the extension of a strongly additive set function defined on a lattice of sets containing the null set to the ring generated by the lattice is reproved. See Section 3.5. LADUBA, I. (1972). Sur quelques gCnQalisations de thkorbmes de Nikodym et de Vitali-Hahn-Saks, Bull. Acad. Polon. Sci., Ser. Sci. Math. Astronom. Phys. 20,447-456. Some generalizations of Nikodym and Vitali-Hahn-Saks theorems are presented for charges on a-fields taking values in a specified space of functions. LEADER, S. (1953). The theory of L,-spaces for finitely additive set functions, Ann. Math. 58, 528-543. A systematic study of V,-spaces is presented. See Chapter 7. See also Notes and Comments on Chapter 7. LEADER, S. (1955). On universally measurable functions, Proc. Amer. Math. SOC. 6,232-234.

APPENDIX 2

295

A real valued function f on a set R is 9-continuous if and only iff is integrable with respect to every bounded charge on 9, where 9 is a field on R. See Section 4.7. See also Darst (1961). LEMBCKE, J. (1970). Konservative Abbildungen und Fortsetzung regularer Masse, 2. Wahrscheinlichkeitstheorie und Verw. Gebiete 15, 57-96. A certain order relation on the set of all real measures on a ring of sets is introduced and the maximal elements in this order are identified. LEMBCKE, J. (1972). Gemeinsame Urbilder endlich additiver Inhalte, Math. Ann. 198,239-258. LIPECKI, Z. (1971). On strongly additive set functions, Coll. Math. 22, 255-256. Another proof of a result of Smiley (1944) is presented. See Section 3.5. LIPECKI, Z. (1974). Extensions of additive set functions with values in a topological group, Bull. Acad. Polon. Sci., Ser. Sci. Math. Astronom. Phys. 22, 19-27. Extensions of group-valued charges are discussed. LIPECKI, Z. (1982). On unique extensions of positive additive set functions, a pre-print. LIPECKI, Z. (1982). Maximal-valued extensions of positive operators, a pre-print. LIPECKI, Z. (1982). Conditional and simultaneous extensions of group-valued quasi-measures, a pre-print. LIPECKI, Z., PLACHKY, D. and THOMSEN, W. (1979). Extensions of positive operators and extreme points I, Coll. Math. 42, 279-284. The result of Plachky (1976) concerning extreme points of a certain convex subsets of ba(R, F ) is generalized. Extensions of results of Jlos and Marczewski (1949) are derived in a Functional Analytic setting. LLOYD, S. P. (1963). On finitely additive set functions, Proc. Amer. Math. SOC. 14,701-704. Pure charges on Boolean algebras are characterized in terms of measures on the Stone space of the Boolean algebras. See Section 10.5. LOMNICKI, Z. and ULAM, S. (1934). Sur la thCorie de la mesure dans les espaces combinatoires et son application au calcul des probabilitks I. Variables indkpendantes, Fund. Math. 23, 237-278.

ZOS, J. and MARCZEWSKI, E. (1949). Extensions of measures, Fund. Math. 36, 267-276. The problem of extending a charge from a subfield of a field 9 of subsets of a set R to 9 as a charge is tackled. See Section 3.3. LUXEMBURG, W. A. J. (1963/64). On finitely additive measures in Boolean algebras, J. Reine Angew. Math. 213, 165-173. A special class of Boolean algebras in which every charge is a measure when restricted to some suitable ideal is studied. MAHARAM, D. (1947). An algebraic characterization of Measure algebras, Ann. Math. 48, 154-167.

296

THEORY OF CHARGES

Necessary and sufficient conditions are given for a Boolean a-algebra to admit a strictly positive bounded measure. See also Hodges and Horn (1948). MAHARAM, D. (1958). On a theorem of von Neumann, Proc. Amer. Math. SOC.

9,987-994. Lifting exists in complete measure spaces. See Chapter 12. MAHARAM, D. (1972).Consistent extensions of linear functionals and of probability measures, “Proceedings of the Sixth Berkeley Symposium on Mathematical Statistics and Probability (University of California, Berkeley, 1970/71)”, Vol. 2, Probability theory, p. 127-147, Univ. California Press, Berkeley. Let Fa,Q E r be a colIection of fields on a set R and 9 the smallest field on R containing this collection. For each a in r, let p, be a bounded charge on Fa.The existence of a charge on 9agreeing with pa on gafor every a E r is discussed. A simple case of this problem is studied in Section 3.6. MAHARAM, D. (1976). Finitely additive measures on the integers, Sankhya, Series A 38,44-59. Lifting fails to exist in the setting of charge spaces. See Chapter 12. MAHARAM, D. (1977). “Category, Boolean algebras and measures, General Topology and its relation to modern analysis and algebra”, pp. 124-135. Springer-Verlag, Berlin. MARCZEWSKI, E. (1947). Sur les mesures ti deux valeurs et les idCaux premiers dans les corps d’ensembles, Ann. SOC.Polon. Math. 19, 232-233. MARCZEWSKI, E. (1947). Two-valued measures and prime ideals in fields of sets, SOC.Sci. Lett. Varsovie C. R . Cl. ZZZ.Sci. Math. Phys. 40, 11-17. Let 9be the smallest field on [0,1] containing all sub-intervals of [0,1]. There is no non-trivial two-valued measure on 9. MARCZEWSKI, E. ~-(1947).IndCpendance d’ensembles et prolongement de mesures (Rksultats et Problkmes), Coll. Math. 1, 122-132. MARCZEWSKI, E. (1948). Ensembles d’indkpendants et leurs applications a la thkorie de la mesure, Fund.Math. 25, 13-28. MARCZEWSKI, E. (1951). Measures in almost independent fields, Fund.Math.,

38,217-229. This paper and the two papers above deal with the following problem in all its facets. Let 9-, a E r be a collection of fields on a set 0 and 9 a field on R containing all 9,’s. Let pa be a probability charge on Fa for each a in r. Is there a common extension p (with a special property) of all pa’s to 9 as a probability charge? This problem is linked with the notion of almost-independence of the fields This problem was also studied by Banach (1948) in the setting of probability measures. MARCZEWSKI, E. (1953). On Compact measures, Fund.Math. 40, 113-124. See Notes and Comments on Chapter 2. MAYNARD, H. B. (1972). A Radon-Nikodym theorem for operator valued measures, Trans. Amer. Math. SOC.173, 449-463.

APPENDIX 2

297

MAYNARD, H. B. (1979). A Radon-Nikodym theorem for finitely additive bounded measures, Pacific J. Math. 83, 401-413. Necessary and sufficient conditions for the existence of exact Radon-Nikodym derivative in the setting of charges are presented. See Section 6.3. See also Notes and Comments on Chapter 6. MOLTO, A. (1981a). On the Vitali-Hahn-Saks theorem, Proc. Roy. SOC.Edinburgh, Sec. A 90, 163-173. Boolean rings with property (f) are introduced. These include Boolean algebras with Seever property strictly. See Seever (1968) and Definition 8.4.1. Let G be a commutative Hausdorff topological group. It is proved that if wn, n 2 1 is a sequence of G-valued s-bounded charges defined on a Boolean ring with property (f), pointwise convergent and En, n 2 1 is a sequence of pairwise disjoint elements in the ring, then limp+- pn(Ep)= 0 uniformly in n. See also Faires (1976). MOLTO, A. (198 lb). On Uniform boundedness properties in exhaustive additive set function spaces, Proc. Roy. SOC.Edinburgh, Sec. A 90, 175-184. Uniform boundedness of a family of s-bounded G-valued charges defined on a Boolean ring having the property (f) is discussed. See Molto (1981a). NAYAK, M. K. and SRINIVASAN, T. P. (1975). Scalar and Vector-valued premeasures, Proc. Amer. Math. SOC.48, 391-396. Let 9 be a lattice of subsets of a set fl and 9*the smallest a-field on R containing 9. Conditions under which a charge on 9 taking values either in R or in a Banach space is extendable as a measure to 9*are presented. NAYAK, M. K. and SRINIVASAN, T. P. (1976). Vector-valued inner-measures, “Lecture Notes in Mathematics”, Vol. 541, pp. 107-1 16. Springer-Verlag, Berlin. Extension of a vector valued charge defined on a lattice of sets to the a-field generated by the lattice as a measure is discussed. See also Nayak and Srinivasan (1975). NUNKE, R. J. and SAVAGE, L. (1952). On the set of values of a nonatomic, finitely additive, finite measure, Proc. Amer. Math. SOC.3, 217-218. A nonatomic charge whose range is not convex is exhibited. See Section 11.4. OLEJeEK, V. (1977). Darboux properties of finitely additive measures on a 8-ring, Math. Slovaca 27, 195-201. An example of a nonatomic charge defined on a 6-ring which is not strongly nonatomic is given. See Definition 5.1.5, Theorem 5.1.6 and Remarks 5.1.7. OLEJCEK, V. (1981). Ultrafilters and Darboux property of finitely additive measure, Math. Slovaca 31, 263-276. The notion of an ultrafilter-atom is introduced in the setting of a charge space and some of its properties are studied. PACHL, J. (1972). An elementary proof of a Radon-Nikodym theorem for finitely additive set functions, Proc. Amer. Math. SOC.32, 225-228. See Notes and Comments on Chapter 6.

298

THEORY O F CHARGES

PACHL, J. (1972). On projective limits of probability spaces, Comment. Math. Univ. Carolinae 13, 685-691. Let p be a non-atomic probability measure on a a-field 9 of subsets of a set R. If there exists a p-pure sub-field of 9, then there is a set A in 9such that p ( A )= 0 and the cardinality of A is at least that of the continuum. See Notes and Comments on Chapter 2. PACHL, J. (1975). Every weakly compact probability is compact, Bull. Acad. Polon. Sci., Ser. Sci. Math. Astronom. Phys. 23,401-405. Let p be a probability measure on a a-field 9 of subsets of a set 0. If there is a p-pure sub-field of 9,then p is compact. See Ryll-Nardzewski (1953) for the notion of a compact measure. PETTIS, B. J. (1951). On the extension of measures, Ann. Math. 54, 186-197. Various extensions of set functions are dealt with. See Section 3.5. PHILLIPS, R. S. (1940). On linear transformations, Trans. Amer. Math. SOC.48, 5 16-54 1. Lemma 3.3 of this paper is Phillips’ lemma. See Section 8.3. PHILLIPS, R. S. (1940a). A decomposition of additive set functions, Bull. Arner. Math. SOC.46, 274-277. Let 9 be a cr-field of subsets of a set SZ and K an infinite cardinal number can be written as a not greater than the cardinal of R. Every p in ba(R, sum p l+ p z uniquely with pl,p z in ba(R, and pz vanishing on every set of cardinal %K in 9. PIERCE, R. S. (1970). Existence and uniqueness theorems for extensions of zero-dimensional compact metric spaces, Trans. Arner. Math. SOC.148, 1-21. Some comments on countable superatomic Boolean algebras are made. See Chapter 5. PLACHKY, D. (1971). Decomposition of Additive Set Functions, “Transactions of the Sixth Prague Conference on Information theory, Statistical Decision Functions, Random Processes”, pp. 715-719. Publishing House of the Czechoslovak Academy of Sciences, Prague. A general decomposition theorem is proved from which the Yosida-Hewitt Decomposition and the Lebesgue Decomposition of bounded charges follow as corollaries. PLACHKY, D. (1976).Extremal and monogenic additive set functions, Proc. Amer. Math. SOC.54, 193-196. Let 9 be a field of subsets of a set SZ and 9oa sub-field of 9. Let v be a The extreme points of the convex set of all probability probability charge on go. charges p on 9which agree with v on goare characterized. PLACHKY, D. (1980). Darboux property of measures and contents, Math. Slouaca 30, pp. 243-246. Let 9,, and g1be two cT-fields on a set such that 9,,c Let p o be a positive bounded charge on Po.Then po is strongly continuous if and only if every

APPENDIX 2

positive bounded charge strongly continuous.

p

defined on g1whose restriction to gois

299 po

is

PORCELLI, P. (1958a). On weak convergence in the space of functions of bounded variation, Math. Research Center Reports No. 39, Madison, Wisconsin. See Porcelli (1960). PORCELLI, P. (1958b). On weak convergence in the space of functions of bounded variation 11, Math. Research Center Reports, No. 68, Madison, Wisconsin. See Porcelli (1960). PORCELLI, P. (1960). Two embedding theorems with applications to weak convergence and compactness in spaces of additive type functions, J. Math. Mech. 9, 273-292. Weak convergence in ba(@ .F) is characterized using Porcelli (1958a and 1958b). See Section 8.7. See also Notes and Comments on Chapter 8. PORCELLI, P. (1966). Adjoint spaces of Abstract L,-spaces, Port. Math. 25, 105-122. V,-spaces are studied from another angle. See Chapter 7. See also Leader (1953). PTAK, V. (1969). Simultaneous extension of two functionals, Czechoslovak Math. J. 3, 553-569. The results of this paper are relevant to the problem studied by Maharam (1972). PYM, J. S. and VASUDEVA, H. L. (1975).An algebra of finitely additive measures, Studia Math. 54, 29-40. Maximal ideals in the algebra b a ( Q .F) are determined, where Cl is a discrete semigroup which is a totally ordered set with multiplication as max. RAMACHANDRAN, D. (1972). A note on finitely additive set functions, Proc. Amer. Math. SOC.31, 314-315. A counterexample is presented to a conjecture of Yosida and Hewitt (1952) concerning the correspondence between charges on a Boolean algebra and the measures on the Stone space of the Boolean algebra. RANGA RAO, R. (1958). A note on finitely additive measures, Sunkhya 19, 27-28. Another proof of the Yosida-Hewitt (1952) Decomposition of a charge as a sum of a pure charge and a measure is presented. See Chapter 10. RAO, M. M. (1971). Projective limits of Probability spaces, J. Multivariate Anal. 1, 28-57. Some conditions are given for a charge to be a measure. See Notes and Comments on Chapter 2. RICKART, C. E. (1943). Decomposition of Additive Set Functions, Duke Math. J. 10,653-665. Generalizations of a result of Phillips (1940a) are presented.

3 00

THEORY OF CHARGES

RIEFFEL, M. A. (1968). The Radon-Nikodym theorem for the Bochner integral, Trans. Amer. Math. SOC.131, 466-487. Hahn Decomposition Theorem for measures on a-fields is presented using Banach space methods. RYLL-NARDZEWSKI, C. (1953). On quasi-compact measures, Fund. Math. 40, 125-130. Perfect and compact measures are discussed. SASTRY, A. S. and SASTRY, K. P. R. (1977). Measure extensions of set functions over lattices of sets, J. Indian Math, SOC. 41, 317-330. Extension of vector-valued set functions from a lattice of sets to the ring generated by the lattice is examined. SCOZZAFAVA, R. (1978). On finitely additive probability measures, “Transactions of the Eighth Prague Conference on Information theory, Statistical Decision functions, Random Processes, (Prague 1978)”, Vol. C, pp 175-180. Reidel, Dordrecht. Let p be a strongly continuous probability charge on the power set P(n)of an infinite set a. Given 0 < a < 1, there exists a sequence F,, n 2 1of pairwise disjoint subsets of fl such that a = p(Unrl F,) = Cnrl p(F.). SCOZZAFAVA, R. (1979). Complete additivity, on suitable sequences of sets, of a simply additive and strongly nonatomic probability measure (Italian), Boll. Un. Mat. Ztal. B 5 , 16, 639-648. Sobczyk-Hammer Decomposition theorem for nonconcentrated charges p, i.e. p ( { o } )= 0 for every o in R, on the power set P(0)of R is proved. SEEVER, G. L. (1968). Measures on F-spaces, Trans. Amer. Math. SOC.133, 267-280. Nikodym and Vitali-Hahn-Saks theorems are presented for Boolean algebras having Seever property. See Sections 8.4 and 8.8. See also Notes and Comments on Chapter 8. SIERPINSKI, W. (1938). Fonctions additives non complhtement additives et fonctions non mesurables, Fund. Math. 30, 96-99. A non-Lebesgue measurable function on the unit interval [0, 11is constructed where fl ={l, 2,3,. . .}. See Notes and Comments based on a charge on P(L?), on Chapter 11. SINCLAIR, G. E. (1974). A finitely additive generalization of the FichtenholzLichtenstein theorem, Trans. Amer. Math. SOC.193,359-374. An analogue of Fubini’s theorem is established in the setting of charges. SMILEY, M. F. (1944). An extension of metric distributive lattices with an application in general analysis, Trans. Amer. Math. SOC. 56,435-447. Every strongly additive set function defined on a lattice of sets containing the empty set can be extended in a unique manner as a charge on the smallest ring containing this lattice. See Section 3.5.

APPENDIX 2

301

SOBCZYK, A. and HAMMER, P. C. (1944). A decomposition of additive set functions, Duke Math. J. 11, 839-846. Sobczyk-Hammer Decomposition Theorem is proved. See Section 5.2. See also Notes and Comments on Chapter 5. SOBCZYK, A. and HAMMER, P. C. (1944). The ranges of additive set functions, Duke Math. J. 11, 847-851. Some results on the ranges of charges are obtained. See Chapter 11. See also Notes and Comments on Chapter 11. SRINIVASAN, T. P. (1955). On extensions of measures, J. Indian Math. SOC., (N.S.)19, 31-60. Extension of measures is discussed using inner measures. STRATIGOS, P. D. (1980). Extensions of additive set functions, Serdica 6 , 197201. Extension of regular bounded charges on fields of sets generated by u-topological spaces is discussed. SUCHESTON, L. (1967). Banach limits, Amer. Math. Monthly 74, 308-311. Existence of Banach limits is shown using an old-fashioned version of the Hahn-Banach theorem. See Section 2.1. TALAGRAND, M. (1981). Non existence de relbvement pour certaines mesures finiement additives et retract& de PN, Math. Ann. 256, 63-66. Under continuum hypothesis, the author constructs a separable subset of P N - N which is not a retract of PN, where N is the set of all natural numbers with discrete topology and /3 N its Stone-Cech compactification. This example is used to show non-existence of a lifting in the setting of charges. See Maharam (1976) and Chapter 12. TARSKI, A. (1930). Une contribution 42-50.

la thkorie de la mesure, Fund. Math. 15,

TARSKI, A. (1938). Algebraische Fassung des Massproblems, Fund. Math. 31, 47-66. TARSKI, A. (1939). Ideale in Vollstandigen Mengenkorpern I, Fund. Math. 32, 45-63. Weak and strong accessibility of cardinals are discussed and existence of measures on some quotient Boolean algebras is considered. TARSKI, A. (1945). Ideale in Vollstandigen Mengenkorpern 11, Fund. Math. 33, 51-65. There exists a 0- 1 valued charge on a Boolean algebra B vanishing on all atoms of B if and only if B contains a countable set of disjoint elements. THOMSEN, W. (1978). On a Fubini-type theorem and its application in game theory, Math. Operationsforsch. Statist. Ser. Statist. 9,419-423. Sinclair's (1974) analogue of Fubini's theorem for measures in the setting of charges is generalized.

302

THEORY OF CHARGES

THOMSEN, W. (1979). The common domain of uniqueness of the products of finitely additive probability measures, “Transactions of the Eighth Prague Conference on Information Theory, Statistical Decision Functions, Random Processes, (Prague, 1978)”, Vol. C, pp. 31 1-316, Reidel, Dordrecht. Let B(X) be the Banach space of all bounded real valued functions defined on a set X, F a subset of B(X), B(X, F) the closed subspace of B(X) generated by F and B*(X) the dual of B(X). Let p be a real valued function on F such that there exists a probability charge b on P ( X ) such that p (f)= f d& for all f in F. Let U(p) = { f B(X); ~ pl(f) =p2(f) for all pi in BT(X) with pi/F = p } which is the domain uniqueness of p. It is proved that n , U ( p ) = B ( X , F ) . An extension to product spaces is also considered. TOPSOE, F. (1978). On construction of measures, “Proceedings of the Conference on Topology and Measure I (Zinnowitz 1974)”, Part 2, pp. 343-381, ErnstMaritz-Arndt Univ., Griefswald. A general result is proved in Section 8 of this paper from which the result of Smiley (1944) on the extension of strongly additive functions on a lattice of sets containing the null set to the ring generated by the lattice as a charge follows. TOPSOE, F. (1979). Approximate pavings and construction of measures, Coil. Math., 42, 377-385. A condition under which a positive bounded charge on a field of sets becomes a measure is given. See Notes and Comments on Chapter 2. TRAYNOR, T. (1972). Decomposition of Group-valued Additive Set Functions, Ann. Inst. Fourier, Grenoble 22, Part 3, 131-140. Lebesgue-type decomposition theorem is obtained for group-valued charges. TRAYNOR, T. (1972). A general Hewitt-Yosida Decomposition, Can. J. Math. 24, 1164-1169. Yosida-Hewitt (1952) Decomposition of a group-valued charge is presented using Caratheodory process. TUCKER, D. H. and WAYMENT, S. G. (1970). Absolute continuity and the Radon-Nikodym theorem, J. Reine Angew. Math. 244, 1-19. A general discussion about Radon-Nikodym Theorem in various settings is presented. TULIPANI, S. (1979). On continuous and invariant measures for a transformation (Italian), Rend. Mat. 12, 249-256. Let R be a set and T a map from R to R. Existence of a nonatomic, T-invariant probability charge on the power set P ( R ) of R is discussed.

UHL, J. J. (1967). Orlicz spaces of finitely additive set functions, Studia Math. 29, 19-58. Spaces of set functions more general than the V,-spaces (Leader (1953)) are studied. VOROB’EV, N. N. (1962). Consistent families of measures and their extensions, Theory Prob. Appl. 7 , 147-162.

303

APPENDIX 2

This paper treats the problem described in the annotation of Maharam’s (1972) paper in the setting of probability measures on cr-fields. Some combinatorial methods are used to solve the problem. WAJDA, L. (1972). Remarks on infinite products of finitely additive measures, Coll. Math. 25, 269-271. Product charge of a sequence of probability charge spaces is shown to exist. WALKER, H. D. (1975). Uniformly additive families of measures, Bull. Math. SOC.Sci. Math. R. S. Roumanie (N.S.)18,217-222. If K is uniformly Let 9 be a field of subsets of a set 0 and K c ba(0, s-bounded and pointwise bounded, then K is a bounded subset of ba(Cl, 9). For some more results in this direction, see Section 8.5. See also Brooks (1974).

a.

WEBER, H. (1982). Unabhangige Topologien, Zerlegung von Ringtopologien, Math. 2. 180, 379-393. WEBER, H. (1982). Vergleich monotoner Ringtopologien und absolute Stetigkeit von Inhalten, Comment. Math. Univ. St. Pauli 31,49-60. WEBER, H. (1982). Die atomare Struktur topologischer Boolescher Ringe und s-beschrankter Inhalte, a pre-print. WEBER, H. (1982). Der Verband der s-beschrankter monotoner Ringtopologien und Zerlegung s-beschrankter Inhalte, a preprint. WEBER, H. and VOLKMER, H. (1982). Der Wertebereich atomloser Inhalte, a pre-print. WEISSACKER, H. U. (1982). The non-existence of liftings for arithmetical density, a pre-print. The argument presented in Maharam’s (1976) paper is clearly explained. See Chapter 12. WILHELM, M. (1976). Existence of additive functionals on semi-groups and the von Neumann minimax theorem Coll. Math. 35,267-274. A general result which may be considered as a common generalization of a result on charges due to Kelley (1959) and of the von Neumann minimax theorem in Game theory is presented. WOODBURY, M. A. (1950). A decomposition theorem for finitely additive set functions, Abstract presented in Bull. Amer. Math. SOC.56, 171. A forerunner of Yosida-Hewitt (1952) Decomposition Theorem was announced. YASUMOTO, M. (1979). Finitely additive measures on N, Proc. Japan Acad. 55, Ser. A, 81-84. An improved version of a theorem of Jech and Prikry (1979) is established.

304

THEORY OF CHARGES

YOSIDA, K. (1941). Vector lattices and additive set functions, Proc. Imp. Acad. Tokyo 17,228-232. ba(R, 9)is studied from the point of view as a vector lattice. YOSIDA, K. and HEWITT, E. (1952). Finitely additive measures, Trans. Arner. Math. SOC.72,46-66. Yosida-Hewitt Decomposition of a charge into a pure charge and a measure is presented. See Chapter 10.

APPENDIX 3

Some Set Theoretic Nomenclature

1. Empty set or null set is denoted by 0. 2. The symbol R is used to denote an “abstract space” or “whole space” or “master set” which is a nonempty set of elements. The members of R are denoted generically by w . The sets in a collection of sets we consider are usually subsets of R. 3 . Membership. If w is a member of a set El we use the notation ME. If a set E is a member of a collection of sets d , we use the symbol M . 4. Inclusion. For any two sets E and F, EcF indicates that E is a subset of F, i.e. every member of E is a member of F. 5 . Union. If {Ea;a E r} is a nonempty collection of sets, we denote the E, and is defined to be the the set {w ;w E E, union of these sets by UaEr for some a in r}. 6 . Intersection. If {E, ; a E r}is a nonempty collection of sets, the intersection of these sets is denoted by neGrEa and is defined to be the set {w ; w i E, for every a in r}. 7. Difference. If E and F are any two sets, the difference of E and F is denoted by E-F and is defined to be the set {w ;w E E and w & F}. 8 . Complement. If E is any subset of R, the complement of E is denoted and is defined to be the set R - E. by 9. Symmetric difference. If E and F are any two sets, the symmetric difference of E and F is denoted by E A F and is defined to be the set (E-F)u (F-E).

Index of Symbols and Function Spaces

Function Spaces =The space of ba(C q

all bounded charges defined on the field

n. 43 space of all bounded charges defined on the u-field 9l of subsets of R vanishing on the cr-ideal9 in 9l. 140 =The space of all essentially bounded real valued functions defined on R. 90 =The space of all bounded measures defined on the field 9of subsets of R. 50 =The space of all bounded measures defined on the field 9 of subsets of R, when 9 is viewed as a Boolean algebra. 248 133 =The space of all 9-continuous functions defined on R. =The space of all real valued functions defined on R. 88 (This space is topologized in such a way that convergence in this space is precisely equivalent to hazy convergence, see p. 94.) = Thespace of all equivalence classes of B(R, 9, p ) formed under the equivalence relation f - g iff = g a.e. [ p ] . 90 =The space of all TI-measurable functions defined on R 121, 178 such that Ifl” is D-integrable, 1s p < CD. =The space of all equivalence classes of L,(R, 9, p) formed under the equivalence relation f g iff = g a.e. [P I. 178 = The space of all essentially bounded TI-measurable functions defined on 0. 122,178 =The space of all essentially bounded measurable functions defined on 0, where 9l is a u-field on R and 9 is a cr-ideal in ‘3. 137 =The space of all equivalence classes of L,(R, 9) formed under the equivalence relation f - g if f - g is a null function. 138 =The space of all bounded pure charges defined on the field 9 of subsets of a. 248 = The space of all simple functions. 101 =The space of all simple charges defined on the field 9 of subsets of R. 188 9of subsets of

ba(R, %,9)

B(R, 9, p) caW, .%

G(R,9) Y(R9 q C(R, 9, p)

= The

-

a,

INDEX OF SYMBOLS A N D FUNCT!ON SPACES

Sim(R, 9, p)

V,(n, 9, p)

(a,R P I

=The space of all D-integrable simple functions defined on R. =The space of all bounded charges A on 9 absolutely continuous with respect to p and satisfying IlA 1, < co. : Charge space, i.e. p is a charge on the field 9of subsets of a.

307 132 185 87

Operations on Boolean Algebras B Bl9

: Boolean Algebra : Quotient Boolean algebra

18 20

Operations on Charges

AB WP

=The collection of all bounded charges on 9 absolutely continuous with respect to A = a l v l + a2v2+ * ' +a,v,, where a l , a2,. . . , a , are real numbers and vl, v2, . . . , v, are 0 - 1 valued charges on 9. : A,(A)=A(AflB), A E ~BE9fixed. , = maxlsis, p (Fi), P = {Fl,F2, . . . ,F,} is a partition of R in

9. = Positive variation o f j . =Negative variation of-p.

=Total variation of p . = Outer charge induced by p. = Semi-variation

of

p.

: See Definition 3.2.6. : See Definition 3.2.6. : See Definition 2.5.2. : See Definition 2.5.2. : p is absolutely continuous with respect to u. : p is weakly absolutely continuous with respect to v. : p is strongly absolutely continuous with respect to u. : p and Y are singular. : p and v are strongly singular.

216 180 145 45 45 45 86 206 66 66 52 52 159 159 159 164 164

Operations on Functions f' fIf I f vg fAg f = g a.e. f s g a.e.

=Positive part off. =Negative part of f. = Modulus of f. = Maximum of f and g. = Minimum off and g. : See Definition 4.2.4. : See Definition 4.2.4.

11 11 11 11 11 88 88

308

INDEX OF SYMBOLS AND FUNCTION SPACES

I*

= Indicator function of the set A.

O(f, F)

12 134

: See the proof of Theorem 4.7.3.

Operations on Sets =A

=A',the complement of A. = Closure of A. =Interior of A. =Number of points in the set. =The class of all subsets of R. =The collection of all finite partitions of R in 9. = Thecollectionof all finitepartitionsof F i n F f o r F i n F . : Equivalence relation on a set. : Partial order on a set. : Relation directing a set. : The cardinality of the continuum.

6 6 15 15 41 3 15 15 14 13 13 192

Operations in Vector Lattices : Lattice supremum of x and y. : Lattice infimum of x and y. : Positive part of x. : Negative part of x. : Modulus of x. : x and y are orthogonal. : The orthogonal complement of S.

X"Y X)Y

X X

-

I

Ix xl Y

S'

24 24 24 24 24 24 29

Miscellaneous Symbols ,1

II II *

Il*IIP,

1s p

Dlf d& Slf d&

JfP a=6

{O, 1F"

39 : The space of all bounded sequences of real numbers. 33 : Norm on a linear space. : Normson2p(R,9, p)-spacesoronV,(R, 9, &)-spaces.121, 122, : See Definition 4.4.11. : See Definition 4.5.5. : Refinement Integral of f with respect to p. : a and 6 are numbers satisfying la -61 5 1. : The space of all sequences of 0's and 1's.

178,180,183 104 116 23 1 270 17

INDEX A Accumulation point, 15 of a sequence of charges, 265 Additive-class, 2 Additivity uniform, 226 uniform countable, 204 Antisymmetric relation, 13 Atom of a Boolean algebra, 22 of a charge (p-atom), 141 of a field, 7 Axiom of choice, 14 B Bake category theorem, 17, 267 property of, 17 o-field, 17 Banach lattice, 34 limit, 39 space, 33 Base topological, 16 filter, 134 Boolean algebra, 18 atomic, 22 complete, 19 nonatomic, 22 pairwise disjoint elements in a, 21 quotient, 20 Boolean algebras atomic, 22 homomorphism between, 19 isomorphic, 19 isomorphism between, 19

Stone representation theorem for, 20 Boolean a-algebra, 19 Borel-Cantelli lemma, 274 Bore1 a-field on R,12 C Cantor set, 17, 265 Caratheodory extension theorem, 81 measure, 274 Cardinal number, 14 Cartesian product space, 13 Cauchy-Schwartz inequality, 123 Cauchy sequence, 16 weak, 33 Chain, 13 Chain condition countable, 21, 211 Charge, 35 atomic, 213 bounded, 35 convex function with respect to a, 238 density, 41 finitely many valued, 249 general invariant, 41 infinitely many valued, 245 modular, 36, 60 negative variation of a, 45 nonatomic, 141 0-a valued, 35 outer, 86 positive, 35 positive bounded, 35 positive real partial, 64 positive variation of a, 45 probability, 35

310 Charge (cont.) pure, 240 range of a, 249 real, 35 real partial, 64 s-bounded, 41 shift-invariant, 39 simple, 188 strongly continuous, 142 strongly nonatomic, 142 total variation of a, 45 unbounded, 42 Charge space, 87 probability, 179 complete, 265 Chebychev’s inequality, 127 Class additive-, 2 compact, 49,245 equivalence, 14 monocompact, 273 Clopen set, 16 Closed under complementation, 5, 6 under countable intersections, 3 under countable unions, 2 under differences, 3 under finite disjoint unions, 5 under finite intersections, 3 under finite unions, 3 under proper differences, 3 under symmetric differences, 3 Closure of a set, 15 Cofinite set, 3 Compact class, 49, 245 Compact topological space, 16 Condition countable chain, 21, 211 Continuous function, 16 9-,133 Continuity absolute, 99, 159 strong absolute, 159 uniform absolute, 127, 204 weak absolute, 159 Convergence hazy, 99 in measure, 92 of a net, 15 Convergence theorem

INDEX

dominated, 88 Lebesgue dominated, 131 Convex function with respect to a charge, 238 Cover open, 16 sub-, 16

D D-integral, 96 Decomposition E-Hahn, 56 exact Hahn, 57 Decomposition theorem general Jordan, 52 Hahn, 56 Jordan, 52 Lebesgue, 168 Riesz, 29 Sobczyk-Hammer, 146 Yosida-Hewitt, 240, 241 Decomposition theorem for measures on cr- fields Hahn, 165 Jordan, 56 Dense-in-itself set, 16, 251 Dense set, 17 Density charge, 41 Derived set, 236 Determining sequence, 104 Directed set, 13 Dominated convergence theorem, 88 Lebesgue, 131 Dual space, 33 Dual of V,-space, 193

E E-Hahn decomposition, 56 Egyptian fraction theorem, 280 Equivalence class, 14 Equivalence relation, 14 Essential boundedness, 89 Exact Hahn decomposition, 57 Exhaustion, principle of, 143 Extension theorem Caratheodory, 81 Extremely disconnected topological space, 278

311

INDEX

F 9-continuous function, 133 F,-set, 15 Field, 2 atomic, 8 discrete, 3 finite-cofinite, 49 p-pure sub-, 274 nonatomic, 8 superatomic, 151 Filter base, 134 in a Boolean algebra, 19 in a field, 10 Finite-cofinite field, 49 Finite dimensional set, 216 Finite intersection property, 16 Finite partition, 8, 14 Finitely disjoint sequence of charges, 144 Finitely many valued charge, 249 First category set, 17 Function continuous, 16 %-continuous, 133 indicator, 12 @-measurable, 91 measurable, 12 modular, 61 null, 88 simple, 90 smooth, 91 strongly additive, 61 T1-measurable, 101 T2-measurable, 101 Functional induced by a real valued set function, 59 linear, 31 Functions equal almost everywhere, 88 G G8-set, 15 General invariant charge, 41 General Jordan decomposition theorem, 53 Generator, 4

H Hahn-Banach theorem, 32

Hahn decomposition E - , 56 exact, 57 Hahn decomposition theorem, 56 for measures, 165 Hamel basis, 32 HausdorfT topological space, 16 Hazy convergence, 92 Holder’s inequality, 122 Homomorphism between Boolean algebras, 19

I Ideal in a Boolean algebra, 19 in a field, 10 m-,137 Image of a set under a map, 16 Indicator function, 12 Inequality Cauchy-Schwartz, 123 Chebychev’s, 127 Holder’s, 122 Minkowski’s, 124 Infinitely disjoint sequence of charges, 145,258 Infinitely many valued charge, 249 Integral D-, 96 lower, 116 refinement, 231 S-, 116 upper, 116 Interior of a set, 15 Invariant charge general, 41 shift-, 39 Isolated point, 15 Isomorphic Boolean algebras, 19 Isomorphism between Boolean algebras, 19 J Jordan decomposition theorem, 52 for measures on (+-fields,56

K Kolmogorov’s Zero-One law, 265

312

INDEX

L L,-space, 121, 178 Lattice Banach, 34 boundedly complete vector, 29 modulus of an element in a vector, 24 negative part of an element in a vector, 24 normal sub-, 28 normed vector, 34 of sets, 1 orthogonal complement of a subset of a vector, 29 orthogonal elements in a vector, 24 positive part of an element in a vector, 24 sub-, 28 vector, 24 Lebesgue decomposition theorem, 168 dominated convergence theorem, 131 measurable set, 264 measure, 49 Lifting, 268 Limit Banach, 39 infimum, 11 supremum, 11 Linear functional, 31 Linear order, 13 Linear space complete pseudo-normed, 33 normed, 33 Linearly independent set, 32 Linearly ordered set, 13 Lower integral, 116 Lower sum, 115

M p a t o m , 141 p-measurable function, 91 p-null set, 87 @-puresub-field, 274 Maximal filter in a Boolean algebra, 19 in a field, 10 Maximal ideal in a Boolean algebra, 19 in a field, 10

Measurable function, 12 p-7 91 Ti-, 101 T2-, 101 Measurable set Lebesgue* 264 7 - 9 264 Measure, 47 bounded, 47 Caratheodory, 274 convergence in, 92 Lebesgue, 49 nonatomic, 141 positive, 47 product probability, 265 real, 41 Metric pre-compact, 273 Metric space, 16 pseudo-, 16 Minkowski’s 124 Modular charge, 36, 60 Modular function, 61 Modulus of an element in a vector latt i e , 24 Monocompact class, 273

N Negative part of an element in a vector lattice, 24 Negative variation of a charge, 45 Net, 15 convergence of a, 15 sub-, 15 weakly convergent, 33 Nikodym theorem, 204 Nonatomic charge, 141 Nonatomic Boolean algebra, 22 Nonatomic field, 8 Nonatomic measure, 141 Norm, 33 pseudo-, 33 Norm bounded set, 33 Normal sub-lattice, 28 Normed linear space, 33 Normed vector lattice, 34 Nowhere dense set, 17 Null function, 88

313

INDEX

Number cardinal, 14 ordinal, 14

0 0-a valued charge, 35

Open cover, 15 Open set, 15 Order linear, 13 partial, 13 Ordered set linearly, 13 partially, 13 well-, 13 Ordered vector space, 23 Ordinal number, 14 Orthogonal complement of a subset of a vector lattice, 29 Orthogonal elements in a vector lattice, 24 Outer charge, 87 Oxtoby’s category analogue of Kolmogorov’s zero-one law, 265

P Pairwise disjoint elements in a Boolean algebra, 21 Partial order, 13 Partially ordered set, 13 Partition finite, 8, 14 refinement of a, 15 Perfect set, 16 Phillips’ lemma, 206 Polish space, 273 Positive bounded charge, 35 Positive charge, 35 Positive measure, 47 Positive part of an element in a vector lattice, 24 Positive real partial charge, 64 Positive variation of a charge, 45 Power set, 3 Pre-compact metric, 273 Principle of exhaustion, 143 Probability charge, 35 Probability charge space, 179 Product probability measure, 265

Property of Baire, 17, 264 Pseudo-metric space, 16 complete, 16 completion of a, 17 Pseudo-norm, 33 Pure charge, 240

Q Quotient Boolean algebra, 20

R Radon-Nikodym theorem, 174,191 Range of a charge, 249 Real charge, 35 Real measure, 47 Real partial charge, 64 Refinement integral, 231 Refinement of a partition, 15 Reflexive relation, 13 Relation antisymmetric, 13 equivalence, 14 reflexive, 13 symmetric, 13 transitive, 13 Relative topology, 16 Riesz decomposition theorem, 29 Riesz representation theorem, 136 Ring, 2

S s-bounded charge, 41 S-integral, 116 Scattered set, 16,236 Seever property, 210 Semi-field, 2 Semi-ring, 1 Semi-variation, 206 Sequence Cauchy, 16 determining, 104 weak Cauchy, 33 Sequence of charges accumulation point of a, 265 discrete, 258 finitely disjoint, 144 infinitely disjoint, 145, 258 Set Cantor, 17,265 clopen, 16

314

INDEX

Set (cont.) closed, 15 closure of a, 15 cofinite, 3 dense, 17 dense-in-itself, 16, 251 derived, 236 Fu-,15 finite dimensional, 216 first category, 17 Gs-, 15 image of a, 16 interior of a, 15 Lebesgue measurable, 264 linearly independent, 32 linearly ordered, 13 p-null, 87 norm bounded, 33 nowhere dense, 17 open, 15 partially ordered, 13 perfect, 16 scattered, 16, 236 7-measurable, 264 tail, 265 weakly closed, 33 well-ordered, 13 with the property of Baire, 17, 264 a-additivity across a sequence of sets, 253 a-class, 2 a-field, 2 Baire, 17 Borel, 12, 17 discrete, 3 a-ideal, 137 a-ring, 2 Shift-invariant charge, 39 Simple charge, 188 Simple function, 90 Singularity, 164 strong, 164 Smooth function, 91 Sobczyk-Hammer decomposition theorem, 146 Space Banach, 33 Cartesian product, 13 charge, 87 compact topological, 16

complete charge, 264 complete pseudo-metric, 16 completion of a pseudo-metric, 17 dual, 33 extremely disconnected topological, 278 Hausdorff topological, 16 Lp-, 121, 178 metric, 16 normed linear, 33 ordered vector, 23 Polish, 273 probability charge, 179 pseudo-metric, 16 Stone, 21 topological, 15 totally disconnected topological, 16 VP-, 185 vector, 31 weakly complete, 33 Stone representation theorem for Boolean algebras, 20 Stone space, 21 Strong absolute continuity, 159 Strong singularity, 164 Strong topology, 33 Strongly additive function, 61 Strongly continuous charge, 142 Strongly nonatomic charge, 142 Subcover, 16 Sub-field, p-pure, 247 Sublattice, 28 normal, 28 Subnet, 15 Sum lower, 115 upper, 115 Superatomic field, 151 Symmetric relation, 13

T TI-measurable function, 101 T,-measurable function, 101 7-measurable set, 264 Tail set, 265 Theorem Baire, 17, 267 Caratheodory extension, 81

315

INDEX

Theorem (cont.) dominated convergence, 88 Egyptian fraction, 280 general Jordan decomposition, 53 Hahn-Banach, 32 Hahn decomposition, 56, 165 Jordan decomposition, 52 Lebesgue decomposition, 168 Lebesgue dominated convergence, 131 Nikodym, 204 Radon-Nikodym, 174, 191 Riesz decomposition, 29 Riesz representation, 136 Sobczyk-Hammer decomposition, 146 Stone representation, 20 Vitali-Hahn-Saks, 204 Yosida-Hewitt decomposition, 240, 24 1 Topological space, 15 compact, 16 extremely disconnected, 278 Hausdorff, 16 totally disconnected, 16 Topology relative, 16 strong, 33 weak, 33 weak*, 158 Total variation of a charge, 45 Totally disconnected topological space, 16 Transfinite induction, 14 Transitive relation, 13 Tree, 150 U Uniform absolute continuity, 127, 204 Uniform additivity, 226 Uniform countable additivity, 204 Upper integral, 116

Upper sum, 115 Urysohn’s lemma, 17

V V,-space, 185 Vector lattice, 24 boundedly complete, 29 modulus of an element in a, 24 negative part of an element in a, 24 normed, 34 orthogonal complement of a subset of a, 29 orthogonal elements in a, 24 positive part of an element in a, 24 . Vector space ordered, 23 over the real line R, 31 over the field of rational numbers, 31 Vitali-Hahn-Saks theorem, 204 W Weak absolute continuity, 159 Weak Cauchy sequence, 33 Weak topology, 33 Weak* topology, 158 Weakly closed set, 33 Weakly complete space, 34 Weakly convergent net, 33 Well-ordered set, 13 Well-ordering, 13

Y Yosida-Hewitt decomposition theorem, 240,241 Z Zero-one law Kolmogorov’s, 265 Oxtoby’s category analogue of Kolmogorov’s, 265 Zorn’s lemma, 14

Pure and Applied Mathematics A Series of Monographs and Textbooks Editors

Samuel Eilenberg and Hyman Base

Columbia University, New Y o r k

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