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Lecture Notes in Mathematics A collection of informal reports and seminars Edited by A. Dold, Heidelberg and B. Eckmann, Z0rich
263 T. Parthasarathy Indian Statistical Institute, Calcutta/India
Selection Theorems and their Applications
Springer-Verlag Berlin. Heidelberg. New York 1972
A M S S u b j e c t Classifications (1970): 49 A 35, 54 C 65, 90 D 15
I S B N 3-540-05818-4 S p r i n g e r - V e r l a g B e r l i n • H e i d e l b e r g . N e w Y o r k I S B N 0-387-05818-4 S p r i n g e r - V e r l a g N e w Y o r k • H e i d e l b e r g • B e r l i n This work is subject to copyright. All rights are reserved, whether the whole or part of the material is concerned, specifically those of translation, reprinting, re-use of illustrations, broadcasting, reproduction by photocopying machine or similar means, and storage in data banks. Under § 54 of the German Copyright Law where copies are made for other than private use, a fee is payable to the publisher, the amount of the fee to be determined by agreement with the publisher. © by Springer-Verlag Berlin • Heidelberg 1972. Library of Congress Catalog Card Number 72-78192. Printed in Germany. Offsetdruck: Julius Beltz, Hemsbach/Bergstr.
PREFACE
This volume of lecture notes contains results on selection theorems and their applications.
Some of the material of this volume had been
given as seminar talks at Case Western Reserve University during ]969 - 1970. This volume contains nine sections each of them followed by selected references.
We hope this volume will be profitable to
specialists in game theory, dynamic programming,
control theory, mathe-
matical economics as well as to all mathematicians
interested in this
area of Mathematics. I wish to express my sincere thanks to the following Professors: Henry Hermes, Marc Jacobs, Ashok Maitra and Sam Nadler Jr., for several useful suggestions. A particular measure of gratitude is due to Mr. Arun Das who patiently and accurately prepared the final typescript of this volume. My wife Ranjani proof-read the manuscript.
To her I owe my heart-felt
thanks. Finally I wish to express my gratitude to the Indian Statistical Institute for providing the excellent research facilities and to Springer - Verlag for undertaking the publication of these notes.
T. Parthasarathy November 20, 1971
Indian Statistical Institute
CONTENTS
Introduction
. . . . . . . . . . . . . . . . . . . . . . . . . .
I. C o n t i n u o u s
selections
. . . . . . . . . . . . . . . . . . . .
2. C o n t i n u o u s
selections
on m e t r i c
continuum
. . . . . . . . . .
I
3
14
3. C o n t i n u o u s s e l e c t i o n s and s o l u t i o n s of g e n e r a l i s e d differential equations . . . . . . . . . . . . . . . . . . . .
24
4. M e a s u r a b l e
35
5. G e n e r a l
selections
theorems
6. T w o a p p l i c a t i o n s
7. v o n - N e u m a n n ' s
and an a p p l i c a t i o n
on s e l e c t o r s
selections
choice
theorem
8. On the u n i f o r m i z a t i o n
of sets
9.
on s e l e c t i o n
Supplementary
remarks
stochastic
games.
. . . . . . . . . . . . . . . .
of m e a s u r a b l e
measurable
to
49
. . . . . . . . . .
58
. . . . . . . . . . .
65
in t o p o l o g i c a l
theorems
spaces
.....
. . . . . . . . .
76
85
This volume
is dedicated
to my parents.
I 2~rRODU3 t'lo ~ The purpose of these notes is to prove a few selection theorems and to mention some applications of these theorems. briefly outline the contents of these notes.
We will now
These notes are divided
into nine sections. We start with a selection theorem due to Michael,
in section
one, which yields a characterlsation of paracompactness. 2 we are concerned with the following question. exists a continuous selection on subsets of some topological
Suppose there
2 )[ (= space of all nonempty closed
space X), then what can you say about X ?
In other words for what space section on 2 X
In section
X
does there exist a continuous
?
The aim of section three is to show how the existence of continuous
selection for certain set-valued ~aps leads to the
existence of classical solution of some generallsed differential equations.
In section four, we prove a selection theorem due to
Dubins and Savage and then we apply this theorem to prove the existence of optimal
stationary strategies for the two players in
zero-sum two-person stochastic games. In section five we establish the following result due to Kuratowskl
and Ryll-Nardzewskl.
metric space.
Let
F : X --> 2 Y
x " F(x) ~ G # @ ~ e S
Let
Y
be a complete separable
be a measurable map [That is,
whenever G is open in
Y
and
S
countably additive family induced by a field of subsets of Then there is a selector G is open in Y.
Y
such that
X].
f-l(G) e S whenever
We also deduce a few more selection theorems with
the help of this theorem. hypothesis,
f - X->
is the
In section six, assuming the continuum
%~ present an example (due to Orkin) of a non-analytic
subset of [0, I] which is a Blackwell space.
This example depends
on a measurable selection theorem proved in the previous section. In section seven we prove essentially the following measurable choice theorem due to von-Neumann.
Let
T = [0, I] and
arbitrary complete separable metric space. set-valued function from
t.
F
be an
is an analytic
T to X, then there is a Lebesgue measur-
able point-valued function almost all
If
X
f
: T -- X
such that
f(t) • F(t) for
We use this result while characterising extreme
points of sets of vector functions. Given a set E in the cartesian product and Y, a set and
I[X U
of
U
is said to uniformlse E, if the projections E
and
U
through
the set
Y
for each
x ~ ]IX E
above
consists of a single point.
x
X x y of two spaces X
onto
(~x) ,~Y)/] U
X
7[X E
coincide, and if,
of points of
Y
lying
In section eight, we are
concerned with the question of the existence of such uniformising sets. In the last section we mention further results on selection theory with some remarks.
I. CO~21NUOUS SELZCTIONS One of the most interesting and important problems in topology is the extention problem. T~o topolgical spaces given,
and
Y
together with a closed subset A of X, and we ~ u l d
know whether every continuous function to a continuous function U
X
A) into
Y.
f
from
g , A -~ Y
are llke to
can be extended
X (or at least from some open
Sometimes there are additional requirements on
which frequently take the following form ". for every must be an element of a preassigned
subset of
which we call the selection problem, the extention problem,
and presents
Y.
x ¢ X,
f,
f(x)
This new problem,
is clearly more general than a challenge even when
A
is
the null set or a one-point set (where the extention proble= is trivial). Let
X
and
Y
denote topological spaces and
family of non-empty subsets of Y. for
~
every
is a continuous
f : X--
If Y
$ : X -- 2 Y such that
2 Y denote the then a selection
f(x) z $(x) for
x ¢ X.
Example I.I: Let @(x) = u-l(x).
u
: Y -- X
Then
is continuous and
f
be onto.
is a selection for
f(x) ~ u-l(x) for every
Example 1.2: Let ~u." X -> 2 Y, let ~A.
Define
~ : X -" 2 Y by
@(x) = V ( x )
if
if and only if
x ~ X-A. f
Define
A < X
if and only if
and
f ". ~ -> Y
is a selection for ~
$
by f
x ¢ X.
~(x) = ~g(x)~
Then
$ ". X --~ 2Y
g if
be a selection for x s A
and
is a selection for
which extends
g.
The selection problem of the first paragraph can now be rephrased as follows : Under what conditions on " X-> ion for
2Y
can every selection for
@, or at least for
@IU
@iA
X,
A : X, Y and
be extended to a select-
for some open set
U ~ A
The purpose of this section is to give a solution to the above problem. Definition" Call ~ : X -~ 2Y lower semicontinuous l.s.c.) if
{x : $(x)~U~@}
is open in
X
(abbreviated as
for every open set U c Y .
The first step in answering the question, is provided by the following elementary but important necessary condition. Proposition I.I'.
If
~ " X -~ 2 Y has the property that, for every
Xoe X, there exists a selection for $~U (U a neighbourhood of which has a preassigned value
yo~ @(xO) at
xo)
xo, then ~ is lower
semlcontinuo us. Exsmple I.I*'. ~
is
I.s.c. if and only if
Example 1.2"" If ~ i s
u
is open.
l.s.c., A is closed in X and g
is continuous,
then ~ is l.s.c. Proof of proposition i.I: Let G = ~x : $(x) ~ V ~ ~}
V
be open in
is open in ~.
Y ~ we must show that
For each
Xo~ G, pick a
Yo ¢ #(Xo): then by assumption,
there exists a selection
for some neighbourhood
xo such that
U*o " Uo ~ x
Uo of
". fo(X) ~ V), then
is ~ontalned in
G.
Hence
f(Xo) = Yo"
fo for #~Uo, Now if
Uo* is a neighbourhood of
G
x0
which
is open and the proof is complete.
One can easily prove the following facts : (i) If
# : X -> 2 Y is l.s.c,
= ~
for every
x
where ~
of V(x) and #(x) respectively, (ii) If
# : X -~ 2Y is
with the property that the function (iii) If
Y
and if
l.s.c, #(x)NU
: X -~ 2 Y is such that and
then
(~x)
~ is l.s.c.
and if
U
is an open subset of
@(x) = U ~ $(x) is
is a topological linear space, and if ~
Y
is non-empty for every x ~ X, then
@ : X -~ 2 Y defined by
l.s.c., then the function
denote the closure
: X-~
l.s.c.
~ " X-,
~Y is
Z Y, defined by ~(x)--eonvex-hull
Now we are set to prove the following important result due to Michael which gives a characterisation of paracompact spaces. X
Recall
is paracompact if it is Hausdorff and if every open covering of
X
has an open locally finite refinement. Theorem l.l: The following properties of a
Tl-space
X
are equivalent
[i]. (a) X
is paracompact.
(b) If
Y
is a Banach space then every l.s.c, function ~'X -~ ~ ( Y )
(family of all closed convex subsets of Y) admits a selection. First we shall establish the follo~ing lemma. ~
~
If
X
semi-continuous and
is paracompact,
function from
X
Y
a normed linear space,
to the ~on-empty convex subsets of Y
r ~ O, then there exists a continuous
f(x) ~ S r ( T ( x ) ) Proof" Let
for every
~ a lower
x ~ X,
where
Uy = ~x : y ~ Sr(~Y(x)) )
f : X -~ Y Sr(Y(x))
for
y s Y.
such that
= ~y~d(y, ~y(x~)qr). Then
Uy = ~x ~ W~(x) C~ Sr(Y ) # ~}. Since y is l.s.c.,
U
is open for every
the open sphere of radius is a covering for
X
r with centre
and hence, since
open locally finite refinement if
~ # ~].
~W~ : ~ ~ A)
y]. X
W~ C V~ .
Clearly
Sr(Y) stands for ~Uy : y ~ Y) it has an
[ We assu~e V~ # V
there exists an open covering
Now we shall construct a family
~Poo : ~ ~ A) of continuous functions from interval with the following properties and
there
is paracompact,
~V~ " ~ ~ A).
By a theorem of Dieudonue, such that
y.
X
to the closed unit
" (i) p~ vanishes outside
~ p~<(x) = I for every x ~ X. By the normality of X c(a A we can find continuous functions q~ : X - ~ [0,I] such that ~ ( x ) ~ l when
(ii)
V~
x s W~
and
~(x)
= O
when
x ~ X-V .
Define
%(x) p~((x)
z
....
~e
Then a
~p~)
satisfies all our requirements.
y(~) ¢ Y
such that
fCx) =
V~ C Uy(~).
z
~e To s e e t h a t
this
neighbourhood U, f
Define
p~(x) y ( ~ ) . A
~rks,
U
Pick for each ~ ~ A~
observe
first
that
each
x ~ X
intersecting only finitely many
x • X
therefore
f
has a neighbourhood on which is continuous on
X.
f
Sr(V(x))
Ivbreover, for each
and hence
Hence
is continuous and
is a convex combination of finitely many
lie in the convex set
has a
V~ and on this
is the sum of finitely many continuous functions.
every
f(x)
"
A
x z X,
y(<), all of which
f(x) 8 Sr(~g(x)).
This
completes the proof of the lemma. Proof of theorem I.I : We will prove first
(a) ~
(b).
To prove
this it is sufficient if we construct a sequence of continuous functions (i)
fn : X -~ Y
such that for every
fn(X) z Srn.2(fn.l(X))
fn(X) ~ Srn(¢(x))
for
for
n = 2,3,...
n = 1,2, ...,
be sufficient, because then the
~fn}
where
for every
We construct fl
~fn}
and
(ii)
r n = 1/2 n.
This will
is uniformly Cauchy and
hence converges uniformly to a continuous f(x) ~ ¢(x)
x ~ X,
f
and that it follows
x z X. by induction.
The existence of a function
satisfying (ii) follows from lemma I.I.
Suppose
fl, f2,...,fn
have been constructed to satisfy (i) and (ii) and let us construct fn+l
to satisfy (i) and (ii).
For each
x ¢ X, let
Sn+l(X) = $(x) ~ S r (fn(X)).
Then
n
@n+l(X) that
is never empty by induction hypothesis.
@n+l is l.s.c.
is open if x° ~ V
U
That is, we must show
is open.
Let us check
={X.@nvl(X) O U W
To do this, we will show that every
has a neighbourhood contained in
Yo e @(x O) and a positive
k < rn
V.
iWow for
such that
W I = { x : $(x) ~ ~ ( f n ( X o ) ) ~
xo e V, pick
Yo ~ ~ ( f n ( X o ))"
Let
U ¥ @ } ,
W 2 = ~ x : fn (x) 6 Srn.k (fn (xo))) .
Clearly
W I is open since
is continuous:
and
can apply lemma I.I
xo ¢ W I N
l.s.e, and
W 2 C V.
!(fn(X))
for every and
x.
(a) ~
collection
(b) ~
P
Y = ~i(~)
(a).
E L y(U)L Ge~
Clearly
C
@(x) -- C
~ ~ y " y e Y,
Let ~ b e
Y
E
~
of
X
has a partition
to the non-negative and every
y(U) = O
i < oo }.
U a ~ZL and Y.
for every
x e X.
p e P
an open covering of
is a Banach space.
for every
for every
X
x 6 X
LM(U)
is a closed convex subset of
@(x) e ~ ( Y )
I.S.C.
This completes
To show this~ it is enough
for every
= { y i y . ~L--> R,
Plainly
is
(#(x)).
of continuous functions from
C = { y : y e Y, y(U) _> O
Clearly
such that
subordinated to it, this means that there exists a
E p(x) = I peP vanishes outside some U e ~ .
tiy Ii =
We
(b).
reals such that
Let
#n+l is l.s.c.
fn+l : X -~ Y
fn+l(X) ~ Sr
if we establish that every open covering P
fn
n+l
Now we shall prove
of unity
is open for
But then
nthe proof of
WE
Since
to find a continuous
fn+l(x) e Srn+l(¢n+l(X)) fn+l(X) e S r
¢ is
X.
Here Let
E y(U) = I }.
~ow for
x • X, let
U ¢ ~Lwlth
x ~ U }.
We will now show that
Let us first o f all show that, for every there exists a
y' a C
such that
for only finitely many pick
U1, U 2 . . . .
U ¢ ~LL.
Un ¢ ~
~jy-y'll~ ~
y'(U) -- 0
if
y(Ui~=y'(U i) for
such that
y(U i) > 0
i = 2,3,... n.
Now we will show that
@
is l.s.c.
y'
and
U I, U 2 . . . .
Since
y(U i) ~ 0
of
that
@
:
x
neighbourhood of Y' ~ ~(x')
for ~ Ui x.
y e @(x) and
Un
i
and y' e C
y'(U I) = y(U I) + 1-6 and
To show this it is
if
x' ~ U, there exists a
Suppose, therefore, that
for all
y' satisfies all our require-
then there exists a neighbourhood
that, for every
y'(U) ~ 0
It is easy to see that
enough if we establish the following ~ O,
~ ~ O,
¢/2, and then define
U ~ ( UI, U2, ... U n } ,
li y-y' Li_~ 2(I-~) ~ ~, and therefore ments.
and
and
To find such a y', we need only
Y(U I) + Y(U 2) + ... + Y(U n) = ~ ~ 1 by
y ~ C
x ~ X, U
of
x
y ~ @(x), and in
y' E @(x') with ~ > 0
be as given above.
X
such ily-y'li~¢.
are given, and let Let
u = UI ~ . . .
NUn.
i = 1,2,... n, it follows from the definition for
i = 1,2,... n
and hence
U
is indeed a
It also follows from the definition of
for every
x' ~ U, and therefore
U
~ that
satisfies all our
requirements. By assumption (b), there now exists a selection For each
U ~ ~I, define
fu " X --~ ~
by
to ~b6, since
for
@.
fu(x) = If(x)] (U).
now follows immediately from the definitions that is a partition of unity on
f
It
~ fu : U ~ ~ }
X, and this partition is subordinated
fu vanishes outside
U
for every
U ~ ~.
This
completes the proof of the theorem. Remark I.I : Even if
X
is the closed unit interval in the above
theorem, (b) becomes false if as the following example shows.
Banach is replaced by 'normed linear'
Example 1.3 • Let
X
be the closed unit interval.
exists a separable normed linear space and a $ : X -> ~ ( Y )
( = closed convex subsets of
Then there
l.s.c, Y)
function
for which there
is no selection. Proof: Let
Z
be the set of rationals in
ordered as a sequence
Zl, z2, . . . .
y(x) # 0
for only finitely many
y(x) _~ 0
for all
/
x ¢ Z }.
C
if
X, and suppose
Let
Y = {y : y E
x ¢ Z ~ .
Finally
x ~ X-
Let
Z
is
~(Z),
C =~y'y ¢ Y,
let
Z
¢(x) C ~{
y " y ~ Y, y(z n) _> I/n }
It is easy to check that no selection for Suppose each
zn z Z
¢ is
l.s.o.
if
x -- z n.
Let us show that there is
¢.
f
were a selection for
has a neighbourhood
kf(x)](z n) • I/2n
X
f
is continuous,
such that
By induction pick a sequence k of distinct integers such that znk+l ~ ~ U for all k. i=l n i
{nk} Then
whenever
U n in
$ , since
x ~ ~n"
{ ~nk } is a sequence of closed subsets of
intersection property, then
and hence there is an
[f(Xo)](znk ) • 0
for all
X
with co finite
xo ~
~ k=-I
Unk.
But
k, which is impossible.
As applications of the above theorem we cite the following two propositions " Proposition 1.2 " Let and
X
be a paracompact space,
$ : X -~ F~(y), a l.s.c, function.
re(x) = inf { ~ l.s.c,
with
m(x) > O.
y ~L : y ~ ~(x) }
p(x) Z 0
for all
Y
Let
and suppose that x,
and
Then there exists a selection
a Banach space
p : X -~ R
p(x) > re(x) whenever f
for
$
such that
is
I0 llf(x) il_~ p(x) for every
x ¢ X.
~¢(x) N{
\ {o}
(x)
Let
y : Y ¢ Y, ~ Y
--> ~ ( Y )
• X
by
is
l.s.c.
@(x) -- y(x----~then
@
Hence if we define is also
l.s.c.
by the above theorem, there now exists a selection and
f
p(x)>0
i: p(x)--0.
It is not hard to check that ~ @
~ ~ p(x)} if
f
Hence
for
@
satisfies all our requirements.
Proposition 1.3 :
A topological space
X
is paracompact if and
only if it is dominated by a collection of paracompact subsets. Before proving proposition
1.3, we ~dll start with a
definition. Def~nltion :
Let
X
closed subsets of
be a topological space and d5 a collection of
X.
Then <~ dominates
X
if, whenever
A ~ X
has a closed intersection with every e l ~ e n t of some subcollection ~I
of
~
R _ ~
which covers .
is closed.
If
If ~ dominates Y
f
f~B
is closed.
and if
(~I C
6~ then
~/ ~ I
f ".%Jd31 -~ Y
is continuous for every
B ¢ ~I,
is continuous.
Proof of proposition 1.3 " we need only take 6 part.
X
A
is any topological space and if
is a function such that then
A, then
The " o n l y if'' part is obvious, since
= { X } .
Let us therefore prove the ''if''
By theorem I.I, it is sufficient to prove that if
Banach space, and selection.
So let
~ . X-~ Y
and
~I(y) #
is
l.s.c., then
~
where ~ ~
, and
h
is a selection for
# I U
.
is a
admits a
be given, and let us find
Consider the class J~ of all couples of the form
Y
f. (~, h)
We partially
II order o~ in the obvious manner.
From the remark made above, it
follows that every simply ordered sub-class of ~ upperbound,
and hence, by 2orn's lemma, ~
say (~o,ho).
f = h o.
Suppose ~ o # ~ :
B e ~
B duo .
Let
with
has a maximal element
We need only show that ~o = ~
simply take
selection for
~ i B~
B ~(~o
has an obvious
, for then we can
then there exists a
) = B*.
Now
and hence by theorem I.I
holB*
is a
and lemma 1.2
(stated and proved below) it can be extended to a selection for
$ ~ B.
If we now let
hi : U ~ - " if
Y
by
x z B, then
than
h l ( X ) = ho(X)
(~l,hl)
(~o,ho).
~ I = ~ B }~3 ~ o if
g
and define
x SU~o
and
hl(X)=
g(x)
is an element of ~ which is larger
This contradicts the maxi~ality of
(~o,ho)
and
thus the proof is complete. Lemma 1,2 :
If
elements of ~
~
C_ 2 Y
contains all one-point subsets of
, then the following t ~
properties of ~
are
equivalent. (a)
Every lower semicontinuous
(b)
If
(where Proo_____f: let
V
0 . X ---~ A
O " X--~ ~
admits a selection.
is l.s.c., then every selection for
0 ~ A
is a closed set) can be extended to a selection for
That (b) =~ (a) " X -~ ~
is obvious.
be l.s.c., let
a selection for ~
.
Let
To show that
A c X
@.
(a) =~ (b),
be closed and let
g
be
~ : X -~ ~f be defined as follows.
$(x)-- { g(x) } = ~(x) It is not hard to check that
for
x s A
for
x
@
is
s
X-A.
l.s.c., hence admits a selection
by assumption (a) and this selection has the required properties and the proof is thus complete.
12 For the proper understanding theorem I.I and theorem 1.2 (stated below without proof) the reader should keep in mind the following consequence of lemma 1.2, where tion space with respect to continuous If
~
c
g : A -~ Y
2Y
itself, then (a)
Every
(b)
Y
is called an exten-
if, for every closed
A < X, every
can be extended to a continuous
contains every one point subset of
Y
f " X -~ Y.
and also
Y
(a) ---->(b) below : l.s.c.
~ ". X - ~
~
admits a selection.
is an extention space with respect to
Theorem 1.2 : Y
X
Y
If
X
X.
is paracompact and zero-dimensional and if
is a complete metric space, then every lo~er semicontinuous
function
~
from
X
to the non-empty, closed subsets of
Y admits
a selection. Proof of theorem 1.2 is similar in nature to the proof of theorem I.I and hence omitted. L~ecall that if every finite open covering of refinement, in other words,
X
X
X
is zero-dimensional
has a disjoint finite open
has a base consisting of sets which
are both open and closed]. The significance of theorem I.I lies in the fact that it is the first characterisation of paracompactness which deals with continuous functions rather than coverings.
Further the theorem
Yields the fact that every paracompact space and hence every metric space has property (b) of theorem 1.l.
i3 REFERENCES
[i]
E. Michael,
Continuous selections I,
Ann. of N~th. 63
[1956], 361-382.
[~]
E. Michael,
A survey of continuous selections, Springer-
Verlag Lecture notes in Mathematics, Edited by W. M. Fleischman, on ''Set valued mappings, selections and topological properties of
54-58.
2X'' . 171 [19701,
2.
CONTINUOUS SELECTI03~30~i ~ETRIC COI~TIg~UUM
In this section we are concerned with the following problem " X
is any topological space and
closed subsets of subspace of S
if
X
2X.
f(E) e E
for every
f : S -- X E c S.
Let
X
S
be a
is called a selection on
Suppose there exists a conti-
2X, then what can you say about
words for what spaces on
is the space of all nonempty
with the Vietoris topology.
A function
nuous selection on
2X
X
? In other
does there exist a continuous selection
2X ? Throughout this section we assume
unless otherwise stated. Hausdorff. sets of
X
to be a metric continuum
By 'continuum' we mean compact, connected,
F2(X) will stand for all two-element and one element
X.
A subbase for the Vietorls topology on
X
consists of
all sets having one of the following forms : ~ F ~ F e 2 X, where
G
F ~G
~ ~ }
and ~ F • F ¢ 2X, F
is an arbitrary open set in
X.
But if
metric space, the Hausdorff metric on
2X
induces the Vietorls
topology.
The Hausdorff metric d(%B)
where
~B
= max [ sup p(x,B), A
z 2 X and
if and o~ly if
d
p
on
is a compact
ZX is defined as follows
sup ~(x,A)] B
is the metric on
2 X is compact [I].
X
~ G )
X.
Also,
X
is compact
The purpose of this section is
to prove the following theorem [2]. Theorem 2.1:
If
M
Is a metric continuum for which there is a
continuous selection on Remark 2.1:
Note that if
continuous selection on
F2(M ) X
then
M
is an arc.
is a continuum and if there is a
F2(X) , then there is also a continuous
15
selection on
2 x.
However this does not remain true in the more
general case, for example in the space of reals IS]. Definition : F£(S). to
If
An element
f
is a set and suppose a ¢ S
f
x ¢ S-{a},
Lemma 2.1-
If
S
is a selection on
is an end element of
provided that either each element
or for each
S
S
X,
S
S-~a},
is a set and
Suppose
i -- 1,2,8
f({a,x})= a
f(~a,x}) -- x. f
Is a selection on
has at most two end-elements with respect to
Proof :
with respect
al,a2, as
F~(S), then
f.
are three end-elements.
Then
for
either (i,l) ...
f(ai, x) = ai or
(i,Z) ... Suppose that (l,1) holds. so that Since
f(al, x) = x . Then for
(J,l) cannot hold and
(J,2) must.
(2,2) holds this cannot be
cannot be
as.
J = 2,3,
a2
f(al, aj) = al ' Consider
f(a2, a3).
and since (3,2) holds this
But it must be one or the other.
Suppose on the
other hand that (l,£)holds.Then by a similar argument both (2,1) and (3,1) hold.
But then
f(~a2, a3} ) is both
a2
and
as, which
is also impossible. Lemma 2.2 :
Let
S
be
continuous selection on S
Is a cut-point of
Proof" Let
H
f(~x,c~) = x that
c
and connected,
F2(S).
and
K
and suppose
f
Then each non-end element
is a c
of
S (that is, S -~c} is not connected).
be the set of all points
f(~Y,c}) = c.
otherwise
T2
x
in
S -~c}
be the set of all points Then neither
H
nor
K
y
in
is empty,
would be an end element , f~rther
H
and
such that S -~c} such since K
are
16 disjoint. lemma,
We shall now show, in order to complete the proof of the
that
we show
H
c
is a cut-point of
and
K
are open.
there is an open set
U
f(~Y,C}) = y.
U t H
Hence
S.
Let
To do this it is enough if
x ~ H.
containing
x
so that
By continuity of
such that if H
is open.
f,
y ~ U,
Similarly
K
is
open. Proposition 2.1 " suppose
S be T e (= ~lausdorff) and connected and selection is a contlnuousAon F2(S). Then S contains at most
f
Let
t~o non-cut points. Pro.of :
This follows from lemma 2.1 and 2.2.
Proposition 2.2 : Every continuum
K
of more than one point has
at least t~o non-cut points. Proposition 2.3 : If non-cut points then that is,
K
K K
is homeomorphic
2.1, 2.2 and 2.3. 2.2 and 2.3.
D
_
x
Of course, we have yet to establish propositions
The rest of this section is devoted to the proof of
~
• A simple chain connecting tw~ points X
is a sequence
a ¢ U 1 only, .
The proof is immediate from propositions
We will start with some preliminaries.
space
D
~
and y
UI,U2,...
b s U n only and
- A space in
such that
X
in
of open sets of
Ui f~ Uj # ~
X, there is a continuous
f(O) -- x
Definition : We call y
Un
and
X
X
a
whenever
and X
b
of a
such that
li-jl _~ I.
is pathwise coILuected if for any two points
f(1) = y.
range) is called a path from
and
to the unit interval I,
is an arc.
Proof of theorem 2.1 :
them.
is a metric continuum with exactly t ~
x
to
f~mction
The function
f " [0,I] -~ X f (as well as its
y.
arcwise connected, for any t ~
if there is a homeomorphi~n
points
f " [0, I] -> X
x
such
17 that
f(0) = x
and
f(1) = y.
range) is called an arc from
The function x
to
f
(as well as its
y.
At this stage we would like to make the following observations'. For a proof of these refer [4]. (i)
If
X
is connected and ~% is any open cover of
any two points of
a
and
b
of
X
X, then
can be connected by a simple
chain consisting of elements of '~. (ii)
Every pathwise connected space is connected.
(ill)
Every connected, locally path~ise connected (that is
each point has a nelghbourbood base consisting of pathwise connected sets) X
is pathwise connected.
Definition: A continuum
K (compact, c o ~ e c t e d
irreducible about a subset
A
of
X
proper subcontinuum of
K
contains
is irreduclble between
a
and
One can show that if K
Let
is a point
p ~ X
X
and
A.
If
X
is a set V
be a connected
A-- ~a,b}, we say
X-
~p}
A
p
X - ~p} LThat is, X
K
Tl-Space.
A cut point of
is not connected.
is a cut point of U
whose union is
and
A
of
using 2orn's lemma.
X, we call it a non-cut point of
empty open subsets of
is
and no
is any continuum, any subset
{p, U, V} where
disconnect
A c K
X
b.
K
such that
not a cut point of of
provided
lies in a subcontinuum irreducible about
Definition:
T2-space) in
V
If
X.
X p
is
A cutting X
and
U
are disjoint non-
}~ - ~p}.
The property of being a cut point (in fact, of being a cutting) is preserved under homeomorphism, but continuous maps can destroy cut points. [0, ~ ]
For example consider the map
onto the unit circle in
R 2.
f(x) = (Cos x, Sin x) of
18 ~
:
If
then
K
U ~/{p}
is a continuum and
and
V ~p)
~p,U,V}
defined on
K
K
onto
closed sets U ~ ~p)
Lemma 2.4: then each of
each
x
if
x~
~
P
if
x ~ V
U ~ ~p}, and
[Since
and
f
is continuous on each of the
V ~ ~p), so
f
is continuous.
U ~ ~p} = K-V, U • ~p}
If
K U
is a continuum and and
V
{x, Ux, Vx}
of
V u~ ~p}
is contained in
x e U
inclusion,
is closed in
Thus
K
and
{p,U,V} is a cutting of
contains a non-cut point of
Suppose each point
Ux
U~p}
The part of the theorem in parentheses follows].
they disconnect say
J
U ~ {p}
thus compact.
cutting
But the map
is the continuous image of a connected space and therefore
connected.
Proof:
U ~p}.
by
f(x) = carries
K
are connected (and thus are continuum).
Proof: It suffices to prove the lemma for f
is a cutting of
x
in
K.
U
If both
K.
is a cut point inducing a Ux
and
Vx
meet
V u)~p},
which is impossible by lemma 2.3. U.
by lemma 2.3.
Now
U x <~ {x}
Since
{Ux~{X}
i~ [Ux t# ~x}] xeU
K,
So one,
is a continuum for : x~
U} is directed by
is a nonempty continuum contained in
U. Pick r ~ Uq, then
q ~ x~U ~ LOx~/~x }].
Then
q ~ U r [otherwise
and disconnect it].
Then
Ur
U r ~ {r}
Uq ~ and
U
Vr
(as above) and if both meet
does not contain
Vq<3 ~q} q
which
is a contradiction. Proof of proposition 2.2" cutting (p,U,V) of
K
If
p
is a cut point of
exists, and each of
U
and
K, V
then a contains a
19 non-cut point of no cut point of
K, by the previous lemma. K
On the other hand, if
exists, certainly there are two non-cut points
and the proof is complete. Let
N
be the set of non-cut points of a continuum
suppose a proper subcontinuum
L
show that this is impossible]. {x, U, V}
of
U
say
and
V
K
exists and L ~
U.
of If
L
Then
K
contains
- ~y}
is connected,
[We will
must lie in one or the other of V ~ ~x}
being a continuum itself
and
U • {x}
y # x.
Then
is connected and these
sets meet, so their union is connected. But their union is while
y z V, hence
ion since
L
y ~/ U, hence not in L ,
K
K -~y),
this is a contradict-
contains all the noncut points of
shown that a continuum
and
x ~ K-L, then a cutting
has two noncut points and thus a ~oncut point [VU~x}]
~.
K
K.
Thus we have
is irreducible about the set of its r~n-
cut points. Definitionfrom
b
A cut point
if a cutting
p
in a connected space
{p, U, V}
The set consisting of
a,b
and
E(a,b).
b
is denoted by
defined by : Pl -< P2
if
exists with
and all points
p
Pl = P2
Lemma 2.5" (a)
If
E(a,b)
a s U
separates a and
or
Pl
b ~ V.
which separate
The separation order on
E(a,b).
is a linear order :
a
E(a,b) is
separates a from
This is easily seen to be a partial order on separation order on
X
P2"
In fact, the
(Prove this).
E(a,b) has more than t~4o polnts, its order
topology is weaker than its subspace topology. (b) a
and
b, then
topo Io gy.
If
K
is a continuum with exactly t~o non-cut points
E(a,b) = K
and the topology on
K
is the order
20 Proof." (a) %
It suffices to note that, for
(~ E(a,b)
and
Vp (b E(a,b)
Eta, b) --
p ~ E(a,b), the sets
are open in
: q
E(a,b) and
Ca, b), q < p}
Vp /-~E(a,b) = ~ q" q ~ E(a,b), p ~ q} (b)
If
any cutting
p z K
~p, U, V}
contain one of
a
and
and
p
is not one of
of
K, by lemma 2.4
b.
Thus
a J
or
b, then given
and
p s E(a,b), so
V
each
E(a,b) = K.
From (a), the order topology is weaker than the given topology on K.
Suppose conversely,
assuming that
p
that
U
is not one of
is open in a
or
K
and
meets
K-U.
then form a family of closed subsets of section property (each
But the sets K
p.
If
[r,s] (~K-U
with the finite inter-
Jr, s] is closed in
their intersection (in the compact space U
containing
U
p z (r,s), the closed interval
jr, s] = { q " r < q < s }
ps
First
b, we will show that
contains some interval (r,s) = {q " r < q < s) not, then whenever
p ~ U.
K
K)
by part (a)). is nonempty.
Thus
But
and
which leads to a contradiction.
If
p
is one of a
or
b,
the
argument is similar. :
Every continuum with exactly two non-cut points is a
totally ordered set with the order topology induced by its separation order. D _ ~ : onto
Y
Let
X
and
Y
be ordered spaces.
is an order isomorphism if
x < y <=~ f(x) < f(y).
f
is
I-I
A map and
f
of
X
21 Every order isomorphism is homeomorphism relative to the order topologies on
X
rationals in (0, I) ; form
K/2 n
for
with
Y.
that is,
n = 1,2,.o.
easy to see that p, q ~ P
and
P
Let P
P
denote the set of dyadic
consists of all numbers of the
and
K = i~2,...,2n-I.
Then it is
has no largest or snallest element and if
p < q, then for some
r ~ P,
p < r < q.
Let
D
be any countable linearly ordered set with the following property (i) It has no largest or smallest element p < q
then there exists a
order isomorphic to
with
Let
D
r ~ D
D
(b)
given
with
p ~ r < q.
a
and
b.
p,q ~ D
with
p < q
b
(i.e. f(~
D
onto
P.
But each point
Is a cut point, dividing
x < y ~
D)
D
Note that "
whenever and
x ~ Ap
and
K
is order isomorphic Let
p
into sets y ~ Bp).
K ~
be an order other than and
Bp
It follows that
f(Bp (~ D) form a Dedekind cut of the dyadic
and thus uniquely determine an element
Defining
F(a) -- 0 f
f
of
rationals
extending
and
F(p) of (0, I).
F(b) = I, we have completed the Job of
to what is obviously an order isomorphism,
a homeonorphism of
K
onto
I.
and thus
This completes the proof of
proposition 2.3. With the aid of theorem 2.1, one can prove the following theorem.
is
the~e is an element
P, the set of dyadic rationals in (0, I).
or
D
p ~ r < q.
isomorphism of a
Then
with
has no smallest or largest element
From the remarks made above it follows that to
p, q ~ D
be a countable dense subset of
not containing the non-cut points (a)
If
P.
Proof of proposition 2.3" K
r ~ D
(ii)
For a proof refer [2].
22 Theorem ~:~ %
If
M
is a locally compact separable metric space
for which there is a continuous
selection on
F2(M) , then
M
is
homeomorphic to a subset of the real llne. We close this section with a final remark, namely, if is a metrlzable continuum, exists if and only if
X
then a continuous is an arc.
selection for
X 2X
23 REFERESCES
[i]
K. Kuratowski,
Topology, Vol. I, Acad. Press and
P.W.N.,
[1966]. [2]
K. Kuratowski, S.B.Nadler, and
G.S.Young,
Continuous
selections on locally compact separable metric spaces, Bulletin De L'Academie Polonaise Des Sciences
18,
[1970], 6-11.
[3]
E.
Michael,
Topologies on spaces of subsets,
Try.
Amer.
M_aZh. soc. 71, [1951], 15~-1s2.
[4]
S.
Willard,
General Topology,
Company, [1970].
Addison-Wesley Publishing
3.
CONTINUOUS SELECTIONS
A~D SOLUTiORS OF GENERALISED
DIFFERENTI AL EQUATIONS Let
En
denote Euclidean
origin centered ball of radius
n b
dimensional in
En,
space of all nonempty compact subsets of topology.
and
Bn
a closed,
_~(Bn) the metric
B n with the Hausdorff
We consider the generalised differential equation
x(t) ~ R(x(t)), x(O) = x° ~ E n ( ~ ( t ) where
space,
R - E n --> _~(Bn)
is continuous.
is an absolutely continuous for almost all
t
function
= dx(t) dt
)
(I)
"'"
A solution of equation (I) $
such that
in some neighbourhood of zero,
O(t) ~ R(#(t)) 0(0) = x° ,
a
classical
solution of equation (I) is a continuously differentiable
function
~
with
~(0) = x0
and
O(t) e R ( ~ ( t ) ) f o r
t
in
some
neighbourhood of zero. The aim of this section is to show how the existence of continuous selection for equation (I).
R
For instance,
leads to (classical) if
R
solution of
has convex values,
the existence
of classical solutions of equation (I) may be shown in many ways [2]. This may be proved as follows. for En
R(x),
Let
r(x)
be the clrcumcentre
that is : the centre of the unique smallest sphere in
containing
selection for
R(x) . R.
But
Then
[I, pp. 76-77]
~(t) = r(x(t)),
r
is a continuous
x(O) = x0
has a solution
and this solution is a classical solution of (I). We shall show in this section that if variation,
is of bounded
a classical solution of equation (I) exists, while under
a weaker condition, These conditions map
R
termed property
~
a solution is shown to exist.
are pertinent to the question of when a continuous
Q " [O,T] -~ _~(Bn) admits a continuous selection,
i.e. a
25
continuous map
q " [O, TJ -> En
is shown that if exists.
q
with
q(t) ~ Q(t)
is of bounded variation,
A special case of this is if
Q
k, then one may show
q, also with Lipschitz
k.
We assume, throughout, where
It
is Lipschitzian in the
admits a Lipschitz continuous selection
constant
t.
a continuous selection
Hausdorff metric, say with Lipschitz constant Q
for all
that
~ " E n -> _~(Bn) continuously,
B n is as in the introduction.
of continuous (n norm, and
CLO, T] will denote the space
vector valued) functions on
Cb[O,T]
the compact subset of
[O,T] with the uniform
C[O,T] defined by
Cb[O,T] = { x : x ~ C~O,T], x(O) = x°,Ix(t)-x(t')l~ blt-t'l} . If
Q ~ C(B n)
and
y a En
we use the notation
p(y, Q) = inf { iy-qL " q ~ R } ,
while for
Ql' Q2 ~ -~(Bn),
h(Ql, Q2) denotes the Hausdorff distance between these sets. For
Q " [0,T] -> _9(Bn), define the variation of
subinterval
it - ~
t], ~ > O, denoted by
Vt
•
Let
P
denote a partition of
of points
(Q)
t-~
Property A " lira a- ~0
IT vt~ 0
=
For each
sup PeO
as follows.
it-a, t], i.e. a finite collection
For the partition
P,
k vt't-~ (Q • P) = ~=OZ h(Q(t ~+i ), Q(ty ))
vt (Q) t-~
on the
'
t-~ = to • t I < ... < tk+ 1 = t, and let
set of all such partitions.
Q
~
denote the
define
and
vt (Q, P). t-q
x ¢ Cb[O'T],
(R(x(.))) dt -- 0
vtt-~ (R(x(.))) ~ LI[O,T]
uniformly for
x s
Cb[O , T].
and
26
(Assume
x(t) = x(t) = x(O)
is defined for
Vt (R(x( • ))) t-~ This convention will be assumed throughout,
t-~ < O.
for
t < ~
so that
when necessary). At this Juncture we would like to make the following observations (i)
"
It is clearly possible that the variation
unbounded for some the special case
t, Q
yet
vt~
(Q) ~ L I.
t (Q) Vt_ ~
For example,
is
consider
a point valued function in the interval
[O,1]
defined by J(l-t)
Sin(l/l-t)
~en
t # I
when
t = I.
q(t) 0
(il)
If
R
is Lipschitzian,
say
h(R(x), R(x')) _~ Klx-x'l,
clearly property A is satisfied. Indeed vtt.~ (R(x(.)) ,P) -k k ~=07 h(R(x(t +i)), R(x(t ))) _< K b ~=OZ (t +l-t ) = K b ~ for x a Cb[O,T] . (iii)
Let
R " E n --> ~(B n) continuously and let
We define the variation of Let
R
in
S, d e ~ t e d
~y:
ly-x°l_~ b T}.
V(R,S) as follows.
k
be any finite collection of points yl ,...,yk+l in S such k that Z ly +i _ y ~ _~ b T and let /k denote the set of all such ~=i k collections. Let V(R,S,k) = Z h(R(yi+l), R(yi)) and V(RpS) is i=l defined as sup V(R, Stk) . If V(R,$) < oc we say R has bounded k~A variation in S. Clearly if R has bounded variation in S, then for any
x ~ Cb[O,T] ,
is finite for all In this case,
t
V~.~ (R(x(.)))
in fact
vot(R(x(.)))
in [0,T] and continuous as a function of
Vtt-~(R(x('))) = Vot(R(x('))) - vt-~(R(x(')))o
Vtt_~ (R(x(.))) -- 0
as
~ -~ 0
uniformly in
x ~ Cb[0,T].
t.
and hence
27 (iv) For of
Q.
Q ¢ =C(Bn)
For each
let
x~
Qe
Cb[0,T]
[increasing the radius of notation family.
Fu].
Then
denote a closed we consider
B n by
~
• ~ 0
neighbourhood
Re(x(.)) . [0,T] -~C(Bn].
if necessary but retaining the
~ Re(x(.)) " x e Cb[0,T] )
is an equicontlnuous
One may note that in the proof of theorem S.I, which follows,
the essential point is to conclude that one may obtain a continuous (or measurable) selection r x . x s Cb [O,T] )
If
R~ (x(.)) such that the family
is conditionally co~pact.
Theorem S.l [4]. Let (a)
r x for each
R : En -~ _~(Bn) continuously.
R is of bounded variation in the ball ~y "ly-x°l_~ b T}
equation (I) admits a classical solution on (b)
If
solution on
R
satisfies property
The family
R(x(. ))
each
~i ~ O,
i -- 1,2,..., 6i ~ 0
let
6i -~ 0
as a map of
as
i ~
qo e R(x°).
For each
Let
-61_~ t_~ 6 i.
i x (t) = x° +
for I%
t ¢ [-61, ~i ], and choose - q~l = P(qo' R(xi(6i )))"
r i to
[-61, 26 i]
~(Bn).
For
oo.
as follows.
if
[0,T] to
We assume, without loss of generality,
r i ". [-61, T] --~ En ri(t) = qo
is equicontinuous
-~ 0 as i -~oo and for each ¢i h(R(x(t)), R(x(t'))) ~ ¢i if
be such that,
~t~t'~ { 6i' x e Cb[O,T].
Pick
equation (i) admits a
~R(x(.)) ~ x e Cb[O,T] }
where we consider each
that
4
~O, TJ.
[O,T].
Proof of (a) "
¢i' let
Then,
i = 1,2,... Let
define
ri(t) = qo
if
-61 -~ t_~ 6i"
Define
t I ri( % ) d~ 0
... (2)
ql s ~(xi(~i )) such that We define
rJ(28i ) as
qlI
as the straight llne segment Joining
and extend qo and
qi
28 on the interval
[8i' 2~i]"
We now extend
equation (2). Proceeding inductively, if interval ['~I' j ~i ] choose
xi to xi
[-~I' 2~i]
by
is define on the
q~ ~ R(xi(J~i )) such that
lqij-I - q~L = P(q~-l' R(xi(J~i )))' define rJ((J+l) ~i ) as
q~
and extend ri to [-~I' (J+l) ~i ] as the straight line segment joining qJ-I i and q~ on ~J~i,(J+l) ~i ]. Then extend xi to the interval [-~I' (J+l) 8i ] by equation (2). Continue in this manner until each function that
r i s C[-~I, T]
ri and x i while
is defined on
L-~I, T].
We note
xi ¢ Cb[O,T] , when restricted to
[O,T]. Furthermore we have (i)
iri((j+l) 8i ) _ ri(JSi)i = ~q~ _ qJ-I ~ i = P(qj-l'i R(xi(j~i))) h(R(xi((j-l) ~i ))' R(xi(J~i )))~ ~i
(ii) Given any ~J~l-ti ~ ~i"
t s [O,T] there exists an integer
j such that
Then
p(ri(t), R(xi(t))) ~ ~ri(t) - ri(J~i)l + ~(ri(JSi ), R(xi(J~i)))
+ h(a(xi(J~i)), a(xi(t))) ~ 3~ i (iii) For any
t,t' z[O,T], let
Lt-J~il ( ~i' Lt'-J'~il ~ ~i" that
J' ~ J.
j,J~ be integers such that Assume, with no loss of generality
Then
~ri(t) - ri(t,)l ~ p(r1(t), R(xi(jsi))) j'-I i + E h(R(x (~+l)~i)) , R(xi(p~i))) + p(ri(t'), R(xi(j'~i))) J'-I 8~ i + E hCR(i((~+l)~i)), R(xi(v~i))]
29 We are now in a position to prove conclusion (a) of theorem 3.1. If
R
that
is of bounded variation, ~ri(.))
is a bounded equicontlnuous
Indeed,
given any
i _~ i*
implies
0 _< ~ ~ ~,
it follows (from observation
8 • O, choose
i~
[ri(t)
ri(t')[
~,
convergent subsequauce {xik( • )}
as desired. ~rik(.)}
From (il) we see
such that for x e Cb[O,T].
i _~ i*, it-t'[ ( 6
Thus
~r i}
Then then
has a uniformly
which converges,
has a uniformly convergent
x 8 C b [O,T]
~ • 0
uniformly for
from (iii), above, it follows that if
C[O,T].
sufficiently large so that
4¢ i • 8/2 ; no,~ choose
vt.~ R(x(.)) < 8/2
sequence in
(iii)
subsequence,
say, to
r.
Then
say converging to
r(t) ¢ i~(x(t)), since
R(x(t)) is
t x(t) :x°+ S r(T)dT. 0 t , x(O) = x °, showing x is a
closed, while taking a limit in equation (2) gives Thus
~(t) = r(t) ¢ R(x(t)) for all
classical solution of (I). To obtain conclusion (b) of theorem 3.I, if property
A
i
satisfies
we find from (iii) that
T T t I [ri(t) - ri(t-~)idt • 48i2 + ~ Vt_~(R(xl(.))) 0 -0
dt.
Now given any
8 • 0 we can use property A to choose a ~ • 0 0 T such that ~ Vt (R(x i (.)))dt < ~/2 if 0 < ~ < Oo, all t-~ 0 i = 1,2, . . . . Next choose i* sufficiently large so that for i _~ i*, T 4 8iT ~ e/2. Then for i _~ i v, 0 _~ ~ < Oo, f [ri(t)-ri(t-~)Idt < ~. 0 By [5, Theorem 20, pp 298], ~ r i} is LIfO,T] conditionally compact. Thus it has an converges,
LILO,T]
say, to
subsequence,
r.
convergent subsequence, Again
convering say,
~x ik) to
~r ik} , which
has a uniformly convergent
x e Cb[O,T].
From (ii) we see
30 r(t) s R(x(t)) almost everywhere, while taking a limit in equation (2) gives
x(t) = x° + Itr(z) d~ or 0 everywhere, x(O) = x°, showing that
~(t) = r(t) s R(x(t)) almost x
is a solution (nOt necessari-
ly a classical solution) of equation (i).
This completes the proof
of theorem 3.1. Remark 3.1 :
The following question naturally arises.
equlcontinuous family
~Q~ " ~ ~ A}
of mappings
when does there exist a measurable selection that the family
~q~ : ~ ~ A}
is
Given an
Q~ " [O,T] -~ _~(Bn),
q~ for each
Q~
such
LIIO, T] conditionally compact.
sufficient condition is shown to be, essentially property (A).
A
It
would be interesting, if one could show the existence of such a family
~q~ • c( a A}
without assuming property (A).
This would then
lead to an existence theorem for a solution of equation (i) with : E n -~ C(B n) merely continuous.
The existence of a solution in
this case seems to be an open question [4]. Remark 3.2 "
We shall show in another section the existence of
measurable selections for continuous or lower-semlcontinuous mappings F : X->
2Y
where
metric space and
X 2Y
is a metric space r
Y
a complete separable
the set of nonempty closed subsets of
the Hausdorff topology.
Y
In general, one cannot expect more than a
Balre selector, indeed if
Q : [O,T] -~ _~(B~) continuously, many
examples exist to show that
Q
need not adz~it a continuous selection.
Consider the following example due to Hermes [3]. Example 3.1 :
For
t ~[0, I]
s(t)-- ~ x - - ~ s ~ , and for
t
• 0
let
with
let
y-- Sin~ : t _ ( ~ a m
}~
E2
31 I A(t) =
Cos I/t
Sin i/t 1
-Sin I/t
Cos I/t
Define
I R(t)
To show
R
show that R
=
A(t) S(t)
if t ~ 0
S(O)
if t-- O
is continuous in the Hausdorff topology, it suffices to R
is continuous at
0.
contains a continuous function
subset of the cylinder t ~ O
But
h(R(t), R(0)) _< ~t.
r, the graph of
S(O) ~ [0, i].
is a connected
But the gap in R(t) for
will disconnect a n y such arc on
continuous on
r
If
S(0) ~ 10,1].
Thus
R
is
[O,1] but there does not exist a continuous point
valued function
r
defined on
[0,I] with values
r(t) ~ R(~).
However one can prove the following theore~ [4]. Theorem 8.2 "
Let
Q ". [O,T] -~ _~(Bn) continuously. vT(Q) • G O
has bounded variation in [O,T], that is, admits a continuous selection
r
where
variation with same variation as Proof :
Choose
J = 0,...,k. (1)
For any
such that
Q
is also of bounded
k, consider the points
qo k ~ Q(O): ql E Q(T/k) and such that
lqk- qkl = p(qk, Q(T/k)), and inductively rk : [O,T] -~ E n
Then
Q
Q.
For each positive integer
O, T/k, 2T/k, ...,T.
r
Suppose
q~ e Q(JT/k)).
as the polygonal arc Joining the points
Define q~,
Then t ~ [O,T] and any
it - JT/kl • T/k.
t ~ [(J-l)T/k, JT/k].
Then
k, there exists an integer
J = J(k)
Assume with no loss of generality, that p(rk(t), Q(t))_< Irk(t) - rk(jT/k) +
p(rk(jT/k), Q(t))_~ h(Q(J-l)T/k), Q(Jr/k))+ h(Q(JT/k), q(t)).
32
(ii)
For
t, t' s LO, T]
and any
k, let J, J'
that
~t-
JT/kl < T/k,
Then
~rk(t) - rk(t')l _~ rk(t) - rk(jT/k) +
be integers such
~t' - J'T/k ~ < T/~.
rk (~T/k){
jl-I Z jrk((~+l)T/k)
-
+ Irk (J'T/k) - rk(t')l
jl- I <
We now show that
~rk}
Z
~ ----j
h(Q( ()/+l) Y/k), Q ( ~ T / k ) )+h(Q(t' ), Q(JT/k)).
is equicontinuous.
k*
sufficiently large so that for
if
Itl-t21 < T/k*.
Next, since
is continuous as a function of uniformly continuous, Vt,t (Q) < s/S
if
~/3
is of bounded variation,
Vt(Q)
on
C0,T], as is
and we can choose a
It-t'L ~ ~.
~ > 0
Then, from (ii), we have : for
Clearly the sequence
uniformly convergent subsequence, Let
t s ~O, TS
that is, set
and
J(k)T/k -> t
J(k) as
Vtt ~ (Q), hence
so that
It-t'l ~ ~, Irk(t) - rk(t')l < s/S + ~/S + a/3 = ~ ty is shown.
~ > O, choose
k > k*, h(Q(tl) , Q(t2)) < Q
t
Given any
~r k)
and equicontlnui-
is bounded hence it has a
say converging to
r ~ CLO, T].
be an integer such that It-J(k)T/kl k -> oo.
Q(t) is closed, it follows that
the desired continuous selection.
k _> k*,
< T/k,
From (i), and the fact that the r(t) ~ Q(t), that is, r
is
This completes the proof of
theo rein S. 2.
Equations of the form (i) arise naturally in many ways. Consider the implicit differential x(O) = x°.
equation
f(t, x, k) = O,
This may be reduced to an equation of the form (I) with
R(t,x) -- ~ v " f(t, x, v) = 0 }.
(Note that here R • [0, I] ×En->En).
Another way in which equation (I) appears is in the theory of control
33 systems having equations of the motion of the form ~ = f(t,x,u), 0 x(O) = x , where the control function u may be chosen as any measurable
r
vector valued function with value at time
a preassigned set
U(t)
R(t,x) =
and one may say
R
t
in
Here
~ f(t,x,u) : U ~ U(t) }
has the representation (f, U).
about control problems in another section.
We shall study
34 REFERENCES
[i]
H. C. Eggleston,
Convexity,
Cambridge Tracts in Mathematics
and Mathematical Physics No. 47, Cambridge University Press London-NewYork, [1988].
[2]
A. F. Filippov,
Classical solutions of Differential Equations
with multivalued Right Hand Sides (Eng. Trans. )
SIAM J.
Control, 5 [1967], 609-621.
[3]
H. Hermes,
The generalised Differential Equation
Advances in Math
[4]
~ ¢ R(t,x),
2 [1970], 149-169.
H. Hermes, On continuous and measurable selections and the existence of solutions of Generalised Differential Equations, Proc. Am~r. Math. Soc.
[5]
N. Dunford, and J. T. Schwartz,
29 [1971], 588-542.
Linear Operators I,
Interscience Pub. Inc., New York, [1958].
4.
MEASURABLE SELECTIONS AND AN APPLICATION TO STOCHASTIC GAMES The aim of this section is to prove a selection theorem due
to Dubins and Savage[7~.We then apply this theorem to prove the existence of optimal stationary strategies for the t~o players in stochastic games. We start with some preliminaries. space with metric
p.
Denote by
closed subsets of A .
~
Let A
be a compact metric
the collection of all nonempty
We introduce a metric
d
on
2
- the
Hausdorff metric (which we defined in section 2), that is, for any A, B e
2
,
d(4
B) = max ~
For any sequence
~ ~
sup p(x, B), x~A : n--1,2,
sup p(y, A)} y~B
... }
define
lim
{ p : p ~ ~ , there exists an increasing sequence of natural numbers such that
Pk
~ ~
and
Pk
n lira An = ~ p • p a A , ~ clear that
lira A
Pn ~ ~
and !ira ~
~
=
k I ~ k 2 < ... -- p } .
Define
n such that
are closed.
Pn -~ p }" In case
we say that the limit exists and denote it by
I~
It is ~
= lira
lira ~ .
Definition . Let X be a metric space and let F be a map from ~h X --> ~ . Call F upper semicontlnuous in the sense of Kuratowski if
xn -~ x
implies
lira F(x n) C
F(x).
Now we would like to make the following observations. (i) ( 4
,d)
is a compact metric space.
(ii) d C ~ , A ) - ~ O
if and only if
lira ~
= A.
36 z~ (iii) F
If
F
is
u.s.c,
is Borel measurable,
subset of
X
that is,
whenever
See Kuratowski
from a metric space
B
X
into
~ x : F(x) ~ B #
is a Borel subset of
2
~ }
, then is a Borel
.
[2] for a proof of these observations.
Now we shall establish the selection theorem of Dubins and Savage.
We shall follow the proof as given in Maitra [3].
be a compact metric space, v
an -~ ao
for all
implies
A
a Borel subset of a Polish space and
a bounded, upper semicontinuous real valued function on
is,
limsup v(an) _< V(ao).
Assume
A? that
Iv(a)i _< H
a ~ A.
Lemma 4.1 : iS
S
Let
Define
v* : 2 A -~ R
by
v*(K) = max v(a). azK
Then
v*
U.S.C.
proof : exists
As
v
ao ~ K
is
u.s.c,
such that
and assume that for some subsequence
and
~ V(an,)
K
v*(K)
compact it follows that there
-----
V(ao).
an ~ Kn,
such that
v*(K n) = v ( ~ ) . v(an,) ->
compact, there exists a subsequence an,, -~ a. limsup
It follows that
Now suppose
a ¢ K
of
and since
{a n,} v
m,
K
Choose a
li--~v*(Kn).
{an,,}
v*(K n) = lim v(a n, ,) < v(a) _< v*(K)
Kn
is
As
A
is
such that u.s.c.
which proves
v*
is
u. s. c,
Le~ma 4 2 :
For each
(K, x) = ~ a : a ~ K is the domain of (K, x) ~ @ 1"
V ) Then
a compact metric space. to
£A.
K ~ 2A and
and
v(a) Z x } .
the set don
x ~ I-N, M]
V
define
Denote by
don V
~ (K,x) : (K,x) E 2 A x [ - M , is closed in
Furthermore
V
is
2A x[-M, u.s.c,
N]
from
(that M]
and
and so don
37 Proof .
Since
element of
v
2 A.
is
Next let us show that
(Kn, x n) ~ dora V, Let
u.s.c., for any real
exists a subsequence
that
dora V
n = 1,2,..., and suppose
a n ¢ ~ (Kn, Xn) , n = 1,2, . . . .
Consequently
c, ~ a " v(a) ~ c }is an
a ~ K
{ank ) and
a ~ V (K, x).
of
x = lira ~nk
A
is compact, there
such that < llmsup
Hence (K, x) z dom
Let
(Kn, x n) -> (K,x).
Since
{an}
is closed.
%
-~ a.
v(%)
_< v(a), so
~, which is, therefore
closed. Finally, in order to prove that show that a n -~ a
V
is u.s.c,
(Kn, x n) --> (K, x), an ¢ V (Kn, Xn) , a ~ V (K, x) •
imply that
Consequently,
since
Since
we have to
n = 1,2,...,
K n -~K,
a~
K.
x = lira x n _< limsup v(a n) _< v(a), a • V
(K, x).
This completes the proof of lemma 4.2. L emma 4,S "
Define
v(a) = v*(K)}.
V
Then
on V
2A
by
V(K) = ~a : a ~ K
and
is a Borel measurable map from
2A
into
2 A" Proof :
As
v
is closed. since
v
Let is
closed, a e K. Let
is
D
u.s.c.
VCK) is nonempty.
Let us show that it
an e V(K), n = 1,2,..., and suppose
an -> a.
u.s.c., v*(K) = limsup v(an) _< v(a) and as Consequently
a e V(K).
be a Borel subset of
2 A.
Hence
V
Note that
K
maps
2A
Then,
is into 2 A.
VCK) = V (K,v*(K)).
Consequently, { K : K ~ 2A
and
V(K) ~ D }
-- proJ [ {(K,x) . (K,x) ~ dora V and tV (K,x) ~ O}~{(K,x)'v*CK)=x~ .
.
.
(i)
]
38 As
v*
is u.s.c,
into L-M, M]
and hence its graph is a Borel set in
(See ~2]). map from
by lamina 4.1, it is a Borel function from
Also
V
dora V
is
into
u.s.c, 2 A.
2A ~L-M,
M]
by lemma 4.2, and so it is a Borel
Consequently,
~(K,x) : (K,x) ~ dora V, is a Borel subset of
2A
V (K,x) ¢ D }
dora V, which being closed in
the former set is a Borel subset of
2 A × [-M,M]
2A ~
~-M, MS,
as well.
Thus
the set within square brackets on the rlght-hand side of (I) is a Borel subset of
2 A × ~-M, MS.
Finally, projection being a
continuous map, and moreover, I-i in this case t it follows by a well-known theorem of Lusln K '. K ~ 2 A
and
is a Borel map. Lemma 4 4 : Define
Ecf
V(K) ¢ D)
be a bounded
u" • S ~
R
by
As
so that
u*(s) is well-deflned.
is
u~(s n) = U(Sn, an) ,
is
~an,,)
is :
U - S -~ 2 A Then
U
u.s.c, Let
by
of
lim U(Sn,,, nl
u*
V
function on
S ~A.
sn -~ s
and suppose
Choose a subsequence M~reover, ~an, )
as
A
such that
~u~(Sn,) )
is compact, an,, -~
a
.
u.s.c., it follows that,
llmsup u*(s n) =
L _ ~
Let
n = 1,2, . . . .
there is a subsequence
Hence
u.s.c,
u*(Sn,) -~ limsup u*(Sn) .
u
Hence
u'(s) = max u(s,a). Then u* is u.s.c. a~A u.s.c., for fixed s, u(s,. ) is u.s.c, in a,
Proo__..~f•
Since
2 A.
that
This completes the proof of lemma 4.8. u
such that
[21, pp 4871
is a Borel subset of
Let
u
Kuratowski
u
an ,,) <
!
u(s,a) • u~(s)
~
~
•
and the proof is complete. be a bounded
U(s) = { a " a ¢ A
is a Borel map.
u.s.c, on and
S ~A.
Define
u(s,a) = max a'¢A
u(s,a')}.
39 Proof of this lemma is similar to lemma 4.3. Next we shall state and prove the selection theorem due to Dubins and Savage. Theorem 4.1 :
Let
u
be a bounded
exists a Borel measurable map
f
u.s.c,
from
S
on
S x~
into
A
Then there
such that
u(s, f(s)) = max u(s,a) for all s. [ In this theorem A is assumed asA to be compact metric and S is a Borel subset of some Polish space]. Proof "
Choose a sequence
valued functions on
4
{Vn} , n : 1,2,... of continuous real
which separate points of
A.
one may choose a sequence of functions dense in
[For instance
C(A)].
For each
vi, define, for K ~ £A, vi(K ) : ~ a : a ~ K Then by lemma 4.3, each be as in lemma 4.5.
Define
By virtue of lemma 4.5 from Since
S
into A
2 A.
Vi
and
vi(a) : sup vi(a') ) . a'~K
a Borel map from Ul(s) = Vl(O(s))
it follows that each
Moreover, for each
is compact and
2A
s,
into
and Un
2 A.
Let
Un(S)=Vn(Un_l(S)) .
is a Borel map
U(s) D Ul(S ) ~ U2(s)
Ui(s) are closed in
U
A
...
it follows
Co
co
f~ Ui(S ) # @. Suppose now that for some s ~ S, a,a' ~ ~ Un(S) i=l n=l and a # a'. Then, for every n, as a,a' s Un(S) , it follows that Vn(a) = Vn(a') , which contradicts the separating property of the OO
sequence
~Vn}.
Hence
a singleton, say,
a = a'
and
for each
s,
(~ Un(S) n=l
is
{f(s)}.
Next, let us show that for every
s ~ S,
~f(s)} = lim
Un(S)
n-)oo
in the Hausdorff metric of Then there exists a
2 A.
~ank } with
Fix
s
and suppose that
ank z Unk(s)
and
~
-~
a ~ limUn(S). a
.
As
40 each
UmCS) is closed and
that
a ~ Urn(s) and consequently, a ~
li--~ Un(S) C ~f(s)). Hence
ank ~ Urn(s) co for all
n
S -~ ~A map from
it now follows that S
into
~A.
As each
Moreover as
f
U
iim Un(S).
is a Borel map from
n
is a Borel measurable
Finally it is Not hard to check that the 2A
is isometric to
is a Borel measurable map from
f(s) ~ U(s)
max u(s,a) for every as A
it follows
Hence
~f(s)} ~
@ " s -~ ~f(s))
class of all singletons belonging to follows that
~ Un(S). n--I
Also it is clear that
~ f(s) ) = lira U (s).
n k _~ m
for each
s s S.
s ¢ S, ~e get
S
into
A.
It
A.
u(s,f(s)) =
This completes the proof of (the
selection) theorem 4.1. Stochastic Games • S, 4
B, q, r.
A stochastic game is determined by five objects :
Here
S
is a nonempty Borel subset of a Polish
space, the set of states of a system: A
is a Nonempty Borel subset
of a Polish space, the set of actions available to Player I ,
B
is a nonempty Borel subset of a Polish space, the set of actions available to Player II ~ q
is the law of motion of the system ,
it
associates (Borel measurably) with each triple (s,a,b) a S x A x a probability measure
q(.Ls, a,b) on the Borel subsets of
S ,
the reward function, is a bounded measurable function on S ~ A
B r,
~B.
Periodically (say, once a day) Players I and II observe the current state
s of the system and choose actions
a
and
b, respectively ,
the choice of the actions is made with full knowledge of the history of the system as it has evolved to the present.
As a consequence of
the actions chosen by the players, two things happen ~ Player II pays player I new state
r(s,a,b) units of money, and the system moves to a
s' according to the distribution
whole process is repeated from the new state
q(. is, a,b). s'.
Then, the
Furthermore, there
41
is specified a discount factor today is worth
8 n at
n
8, 0 _< 8 < i, so that the unit income
days in the future.
The problem, then,
is to maximize the total expected discounted gain of Player I as the game proceeds over the infinite future and to minimize the total expected loss of Player II. A strategy v for Play I is a sequence
~I' w e , " ' ,
where
=n
specifies the action to be chosen by Player I on the n th day by associating (Borel measurably) with each history Sn_ I, an_l, bn_l, sn)
of the system a probability distribution
~n (. lh) on the Borel sets of
A.
A strategy
said to be stationary if there is a Borel map where
PA
h = (sl, al, bl,...,
~
for Player I f
from
S
to
is PA '
is the set of all probability measures on the Borel sets
of A, such that denoted by
~n = f
for each
n > I , and, in this case, ~
is
fco. Strategies and stationary strategies for Player I!
are defined analogously. A pair (~, r) of strategies for Players I and II associates with each initial state
s
an
nth-day expected gain
rn(= , C)
(s)
for Player I and a total expected discounted gain for Player I c<)
I( ~, F) (S) = n=17 8 n'l r n ( ~, F) (s).
The functions
rn(~, F) are, plainly, Borel measurable ;
consequently,
I(=, F) is a Borel function.
A strategy inf F
sup I(~, F)
~* is optimal for Player I (s)
for all r' and all
I( ~*, F') (s) _>
s ~ S , strategy
F* for
7r
Player II is optimal if ~'
if
and
and all
value if
s ~ S.
sup inf I(~, F)(s) _> I(~', F ~) (s) F
We shall say that the stochastic game has a
sup inf I(~, F)(s) = inf sup I(~, F)(s) v
for all
F
for every
s ~ S.
42
In case the stochastic game has a value, the quantity sup inf I(~, F )(s), F ?r function.
as a function on
S, is called the value
The stochastic game problem was first formulated by Shapley [6] who took
S, 4
B
to be finite, assumed that play would terminate
in a finite number of stages with probability one, and considered only what we have called stationary strategies.
Shapley was able to
prove under these conditions that the stochastic game has a value and that both players have optimal strategies.
See [8] or [61.
We
shall prove a generalisation of Shapley's result under suitable assumptions on
S, A, B, q, r.
Specifically, we shall assume that
(1) S, A, B
are compact metric spaces, (ii) r
function on
S ~
and
b n -~ bo,
A ~B,
and (ili) whenever
is a continuous sn J
So,
q(-LSn, an, bn) converges weakly to
an -~ ao,
q(. ISo, ao, bo).
These conditions will remain operative throughout the rest of this section. In order to prove the main theorem, we need some lemmas. X
is a compact metric space, we denote by
probability measures on the Borel sets of
PX X.
If
the space of all It is well-known that
PX, endowed with the weak topology, is a compact metric space. Lemma 4.6 " S ×A
xB.
Let
i
be a continuous, real-valued function on
Then, i(s, ~, k) = IJ i(s,a,b) d ~(a)dk(b), s ~ S,
~ PA' k s PB, is a continuous function on
S x PA ~(PB"
For a proof see [4]. Lemma 4.7 " where
X
Let
u
be a bounded, continuous function on
is a Borel subset of a Polish space and
metric space.
Then
u* . X -~ R
defined by
Y
X ~
Y
is a compact
u*(x) -- max u(x,y) y~ Y
45
is continuous.
Moreover
u, " X --> R
defined by
u. (x) = rain u(x,y) is continuous. y~Y Proof of this lemma is easy and hence omitted. Lemma 4.8 : where
X
u
be a bounded,
continuous function
is a Borel subset of a Polish space and
metric space. into
Let
Y
Then, there exist Borel maps
such that
U(X,g(x)) =
f
Y
y
is a compact
and
u(x, f(x)) = max u(x,y), x z X y~Y
X x
g
from
X
and
rain u(x,y), x ~ X. y~Y
This lemma is an immediate consequence of theorem 4.1. If
X
is a topological space, denote by
all bounded,
continuous functions on
X.
C(X) the family of
For each
w ~ C(X), define
Kw(S,~,k) = r(s,~,k) + ~ I w(-) dq(. {s,@,k), s ¢ S, ~ ¢ PA' k ¢ PB
where
r(s, S, k) = ~I r(s, a, b) d @(a) d k(b)
and
q(.~s, S, k) = 5S q(.is, a, b) d iz(a) d k(b). It follo~s from lemma 4.6, S ~PA
XPB"
Kw
is a continuous function on
From Sion's minimax theorem Is] we have,
sup inf ~PAXSPB
Since
Kw
Kw(S,~,k) =
is continuous on
Inf XSPB
S ~
sup Kw(S,~,k) , s e S. SaPA
PA "( PB
it follows from lemma 4.7 that
sup
by max
Thus, we have
and mln, respectively.
max ~¢PA
mln XSPB
Kw(S,U,X) =
mln XSPB
and
and inf
PA' PB
are compact,
can be replaced above
max Kw(S,~,X) , s ~ S. ~ePA
44 Lemma 4.9 : from
S
For each
into
PA
max
and
w ~ C(S), there exist Borel maps PB, respectively,
f
and
g
such that
rain ke PB
Kw(s , ~, X) = rain k~ PB
Kw(S , f(s), X)
~ e PA
min XeP B
max ~eP A
Kw(S , ~, k) = max 6eP A
Kw(s , u, g(s)), s ~ S.
and
Proof "
We prove the first assertion.
S ~ S, ~ ¢ PA" S XPA.
By lemma 4.7,
~
Let
¢(s,s) = rain Kw(S,~,k) , Xe PB is a continuous function on
Hence, by virtue of lemma 4.8, there exists a Borel map
f " S -~ PA max
rain
~eP A
kaP B
such that Kw(S , ~, X)
~(s,f(s)) = max ~(s,N) = ~zP A for all
s s S.
On the other hand,
¢(s, f(s)) =
min Kw(S , f(s), X) for all X,P B the proof of the first assertion. For each Tw(s) =
w e C(S) define
max ~ePA
min XePB
Len~na 4.10 :
The operator
P_~
Wl, w 2 e C(S).
if
Let
w ~ C(S),
check,
T
T T
~ w Ii denotes
is monotone, we get
This completes
as follows •
Kw(S , @, X) = rain XePB
It is clear from lemma 4.7,
:
Tw
s $ S.
maps
max Kw(S , @, k). ~¢PA
C(S) into
C(S).
is a contraction mapping o n Plainly,
w 1 _< w 2 + LLWl-W211,
sup ~w(s) ~. ssS
C(S). where,
Since, as is easy to
Tw 1 _< T(w 2 + li Wl-W2i~ )
-- Tw 2 + ~liwl-w 2il
45 Consequently and
w 2)
Hence,
Tw~-Tw I _< 8 ~l-W21i , T
Similarly,
Twl-TW 2 --~ 8 ~tWl-W21L
which shows
is a contraction mapping as
(interchanging
wI
II Twl-TW2il ~ ~ ~ Wl-W21L
~ < I.
This completes the
proof of the lemma. Since
C(S), when equipped with the supremum norm, is a
complete metric space,
T
has a unique fixed point in
virtue of the Banach fixed point theorem. fixed point of
T.
Let
w~
C(S), by
be the unique
Then it follows from the definition of
Kw,(S , ~, k) and lemma 4.9 that there exist Borel maps from
S to
PA
and
PB, respectively,
f* and
such that, for every
g*
s ~ S,
w*(s) = min [r(s,f'(s),k) + 8 I w*(. ) dq (.Is,f*(s),k)] kcP B = max [r(s,~,g*(s)) + ~ I w~(.) dq(.Is,N,g*(s))] ~ E PA = r(s,f*(s),
...(*)
g*(s)) + 8 I w*(.) dq(.Is, f*(s), g*(s)).
We shall show after one lemma that
w* is the value function of the
stochastic game. Our next task is to solve the above functional equation (*). To accomplish this, denote by functions on function from to
PB,
S.
With each ordered pair (f,g), where
S to
S to PA
and
we associate an operator
(L(f,~)w)(s) = r(s,f(s),g(s)) We may interpret Player I,
M(S) the f~nily of all bounded Borel
g
f
is a Borel
is a Borel function from
L(f,g) - M(S) --> M(S)
S
defined by
+ ~ S w(.) dq(.Is, f(s),~(s)),
s ¢ S.
(L(f,g)w)(s) as the expected amount Player II pays
when the initial state of the system is
and II take actions according to
f(s) and
g(s),
s,
Players
I
and the game is
46
terminated at the beginning of the second day with Player II paying Player I
w(t) units of money, where
t
is the state of the system
on the second day. Lemma 4,11 " M(S)
and
The operator
L(f,g) is a contraction mapping on
l(fOo gO~ is its unique fixed point in
The proof is straight-forward and omit it.
M(S). Now we are ready
to state our theorem [4]. Theorem 4.2 :
Let
S, A, B
be compact metric spaces, let
continuous, real-valued function on moreover, that, whenever S ,~ A '~ B,
S ~
A
,( B,
converges weakly to
be a
and assume
(Sn, an, b n) -~ (So, ao, b o)
q(. ISn, an, b n)
r
in
q(. !So, ao, be) .
Then, the stochastic game has a value, the value function is continuous, and
Players
I
and
II
have optimal stationary
strategies. Proof:
Observe that the above functional equation (*) can be
rewritten as
L(f*, g~) w* = w ~.
w ~ = l(f.(oo), g,(Oo)).
It follows from lemma 4.11
that
In view of this we have,
I(f*(°°), g*(°°))(s) -- max [rCs,~, g*(s)) + asP A 8 I l(f *(°°),g*(°°))(.)dq(. Is,~,g*(s))]
= min [rCs, f*Cs),k) + ~ I ICf *(9°),g*(e('))( )dq(-Is, f*(s),k)] ke PB It follows from Blackwell
[Theorem 6, pp ~$2, [I]] or from
[Theorem 3.1 in [4]], that,
I(f *(~),g*(~))(s) = sup I (~, g*(~)) (s) 7r
=
inf l(f*(°°) C)(s) F
for
s ¢ S.
47 Consequently, l(f*(°°),g *(°°)) = sup I (~,g,(Oo)) Z inf sup I(~, C ). ?r v ?r On the other hand,
l(f*(°°),g *(°°)) = inf l(f "(°°) c ) < F
sup inf I( ~, V) ~ C
Hence, inf sup I( =, c) = sup Inf I(~, v). C ~ = f This proves that the stochastic game has a value, that the value function is I(f,(oo), g,(OO)) = w~ and so continuous, and that f, (co) g, (oo) , are optimal stationary strategies for Players I and II respectively. Remark 4.1 "
This completes the proof of theorem 4.2.
If in theorem 4.2 we allow
S
to be merely a Borel
subset of a Polish space, our proof breaks down because lemma 4.6 fails.
However, we can eliminate this difficulty by imposing
somewhat stronger conditions on
q
and
r, namely, that
should be a continuous function on
S ~
PA x p B
I w(.) dq (. Is, ~, k) for every when q
and
A
w ~ C(S). and
r,
B with
are finite]. A, B
and that
should also be continuous on [ ~te
r(s,s,k)
S ~
PA ~
that these conditions will be satisfied Then under these conditions on
compact metric spaces and
S
a Borel subset
of a Polish space, the conclusions and the proof of theorem 4.2 remain valid.
PB
48
REFERENCES
[1]
D. Blackwell, Stat
S6 [1968],
[2]
K. Kuratowski,
[3]
A. Maitra,
A. Maitra
226-235.
Topology
Vol I, Acad. Press, P.W.N. [ 1 9 6 6 ] .
Sankhya Series A. 30 [1968], 211-216.
and
T. Parthasarathy,
Jour. optimi, theory
[5]
Ann. Math.
Discounted dynamic programming on compact metric
spaces,
[4]
Discounted dynamic programming,
T. Parthasarathy
and
t~o-person games,
On stochastic games,
And its Appl , 8 [1970], 289-~00.
T.E.S. Raghavan,
Some topics in
American Elsevier Publishing Company,
New York [1971].
[6]
L. S. Shapley,
Stochastic games,
Proc. National. Acad. Sci
U.S.A., 39 [1983], i095-II00.
[7i
L.E. Dubins and L.J. Savage, Fow to gamble if you must, Xcgraw-~Ki!, New Yor~ [1965].
5.
GFz~ERAL THEORE~S ON SELECTORS
In this section we shall first prove a general theorem on selectors
due to Kuratowski
theorems on selectors Jacobs
and
[2].
Ryll-Nardze%,ski
and deduce a few
Lastly we shall state a theorem of
[3]. Let
space.
X
be a set o f arbitrary elements
Let
S
be a countably
additive
and
Y
a metric
family of subsets of
X
cO
[that is, if
An a S
for
the following statement Lemma 5.1 "
Let
f(x) = lim fn(X)
fn " X -- Y
Let
assumption Ifm
for
whenever
whenever
K = ~
c Y.
G
I/n
for
Then
G
Let
and let
is uniform.
is open in
is open in
Suppose that
Y
(I) n.
Y.
K n = ~ y " p(y, K) _<
there is a sequence
- fL _<
U An ¢ S ]. n=l
n = 1,2,...,
where the convergence
f-l(G) ~ S
Proof "
then
is true.
fnl(G) s S Then
n = 1,2,...
m I < m 2 < m 2 < ...
n = 1,2,
....
I/n }.
By
such that
We shall show that
n oo
f-l(K)
First,
let
x ~ f-l(K),
=
/h n=l
that is,
f-I mn
(Kn)"
f(x) ~ K.
As
Ifm (x) - f(x) l~ I/n, n
we have
finn(X) z Kn,
that is,
x E f-I (Kn)
for each
n.
Let
mn
fm (x) ¢ Kn, n
that is,
P(fm (x), K) _< I/n. n
As
f(x) = lim n---oo fmn(X),
it follows that (owing to the continuity of the metric) P(f(x), K) = 0 of our lemma.
and hence
f(x) ¢
K = K.
that
This completes
the proof
5o Let B
L
be a field of subsets of
are members of
Denote by
S
L, then so are
X.
A[3 B,
[In other words, if A ~B
Theorem 5.I [4] :
Let
Y
L, that is,
L.
be a complete separable metric space.
F : X -~ 2Y (the space of all closed nonvoid subsets of
be such that
~ x " F(x)/A G M @ } ~ S
Then there is a selector whenever Proof : Y.
X - A].
the countably additive family induced by
the family of countable unions of members of
Let
and
G
is open in
Let
A
f :
X->
whenever
Y
G
such that
Y)
is open in
Y.
f-l(G) c S
Y.
R = (rl, r2, ..., ri, ...) be a countable set dense in
We may suppose of course that the diameter of
shall define
f
as the limit of mappings
n = O, 1,...,
satisfying condition (I) n
Y
is
fn " ~ -~ R
< I.
We
where
and the two following
conditions.
(2) n
...
P(fn(X), F(x)) <
i/2n
(3)n
-.-
ifn(X) - fn_l(X) J <
I / ~ ~-I
for
n > O.
(The basic idea of proof is similar to the proof of theorem I.I). Let us proceed by induction. Thus
(I)°
given (2)n_ I.
and
n ~ O,
(2)0 that
Put
fo(X) = r I
are fulfilled, fn-I
for each
f4ow let us assume, for a
satisfies conditions
(1)n_ 1
Put n Ci
=
~ x "
n
D i -- { x : =
n Ci
P(ri, F(x)) < I/2n } ,
Ir - fn_1(x)! < 1/2n-z /h D n i "
x ¢ X.
},
and
51 We have,
X = ~
k9 ~
X, there is by Since
tJ . . . .
For,
(2)n_l, y ¢ F(x)
~ rl, r2, ... }
~r i - yL < 1/~ n
and
being a given point of
such that
}y - fn.l(X)i _< i/2 n-I .
is dense, we can find a iri - fn.l(X) l < 1/2 n-l.
B ni
Denote by
x
the open ball
ri Hence
such that x s ~.
{ Y " IY - rll • 1/2 n } •
It
(B~-I) . = ~ x " F(x) (h B ni # @ } and D ni = fnll n n Hence it follows that C i ¢ S coand D i e S and consequently follows that
~e
S.
~
Consequently
A~ = j=l h]
~i 'J '
where
the double sequence (i,J) in a simple sequence s = 1,2,...,
~i, J ¢ L. (ks, m s )
Arrange where
and put
s~ms
We have,
X = ~
~
~
tJ
...
~s t9 ...
This identity allows us to define a mapping fn(X) = rks fn
if
satisfies
fnl(rk
x • ~s"
(~I ~ "''wEns-l)"
(1)n, (2) n and (3) n.
) = Esn - ( ~ 1 ~
...
fn " X -~ R
~ ~s_l ).
as follows"
We shall show that
By definition
As
L
is a field,
it follows
s that
fnl(rk ) ~ L s
fn I (r i) e S
for each
Z ~ R (since (I) n
R
fn I (r i) =
i.
~J fnl(rk ), we have k s= ~ s
Consequently
is countable and
B
fnl(Z) ~ S
for each
countably additive).
Thus
is satisfied. For a given
Put
and as
k s = i.
clear that
x
let
Hence we have
s
satisfy,
x ~ Esn C
fn'S satisfy (2) n and (3) n
~
= Cin C~ D nl
and it is
Thus the sequence
52 fo' fl' "'', fn "'" (1)n, (2) n By (3) n
and
has been defined according to the conditions
(3) n.
and by the completeness of the space
converges uniformly to a mapping
f . X --> Y.
follows
is open in
f'l(G) e S
whenever
f(x) e F(x) according to
G
(2) n.
Y, this sequence By lemma 5.i, it Y.
Finally
Thus the proof of theorem S.l is
complete. Remark 5.1 : [namely by
The theorem remains true by replacing the condition
~ x " F(x) C~G # @ } E S
~ x "
F(x)~
K # ~ } e L
can be seen as follows. F
set
:
G = K IU
Y
K2•
whenever
whenever
G
is open in
K c Y
is closed.
being metric, every open ...,
where
Y ]
Kn = ~n"
This
G <
Y
is an
Hence
O0
x :
Remark 8.2 "
F(x) ~ G # ~ }
~9 { x : F(x)(AK n ~ ~ } n=l
For each complete separable metric space
a choice function f
=
f . 2Y -~ Y
Y, there is
of the first class of Baire.
may be assumed to be continuous if
dim Y = O
observations can be seen as follows. 2Y
identity mapping defined on topology,
the sets
K " K ~Q
{ @ }
is closed in
Y.
F~
in
2Y,
~ K :
2Y.
G
is
K ~ G ~ @ }
F
hence a member of
and
G8
and
X = 2 Y, F = the
According to the Vietoris
are closed in As
F~
Y
These
Put in theorem 5.1,
which are
Also
(that is, if
contains a countable base composed of closed-open sets).
L = field of subsets of
~ S.
2Y
provided
in L.
are open and the sets
Y,
so
G
is open and
~ K " K ~ G # ~ }
Q is
It is not difficult to check
(from theorem S.l) that there is a choice function of the first class of Baire, that is,
f'l(G)
is an
f "
2Y -~ Y
F~
set for
53 every open
G
we denote by
in L
Y.
to
S.
G = QI ~ Q2 ~3
...,
~ K . K ~ Qn # ~ ) ~ L
Since the members of
f-l(G)
dim
the field of closed-open subsets of
assumption we have Consequently
In the particular case where
where
and
Qn
Y = O,
2 Y.
By
is closed open.
~ K " K ~G
# ~ ) belong
S are open sets, it follows that
is open for every open set
G
in
Y
and hence
f
is
continuous. Now we shall deduce the following t ~ Theorem 8.2 ~2~ : be a
Let
X
theorems from theorem 8.1.
be a set with
~-ring
S
and let
T2-space which is the union of a family of at most ~
Y (= first
uncountable ordinal) compact metrizable subspaces in such a way that any compact subset of subfamily.
Let
Y
F :
X-~
F-I(c) = ~ x : F(x) ~ C Then there exists an x s X
and
2Y
(closed subsets of
# g ~ ~ S
f : X -~
f-l(c) ~ S
Definition :
lies in the union of an utmost countable
Y
whenever
~enever
such that C
C
Y).
Suppose
is compact in
f(x) ~ F(x)
is compact in
for every
Y.
A Lusin space is a separable metrizable space which is
the image of a complete separable metric space under a continuous I-I function. Theorem 5.~ . Lusin space.
Let Let
X
be a set with
~-algebra
S
and
Y
be a
F : X -~ 2 Y (= nonempty closed subsets of
Y).
Suppo s e
x :
F(x) ~ B
Then there exists an x
and
Y.
f-l(B) ¢ S
# ~ )
¢ S
f " X ~
Y
for every Borel set such that
for every Borel set
B
B
in
Y.
f(x) ~ F(x) for every in
Y.
54 Proof of theorem 6.2 : the hypothesis be
Let the family of compact sets described in
{ Y< ". ~ • w }
than or equal to ~L .
For each
where
w
~ • w,
is an ordinal less
define
X~ = F-I(Y~) - <J{ F-I(Y~) : 8 • ~ }.
Clearly, the
pairwise disjoint, and their union is
X.
a-ring
S
obtained by restricting
fact, a a-algebra on
X
3
(that is
and each of the sets since
X
to
S~c
for all
~ < w,
a point-closed function
S
for all
if
x e X<.
It is clear that
complete with any compatible metric. f~
such that
every closed subset
C
of
f~(x)~ Yd"
f(x) = f~(x)
Clearly,
f
is a selector for
every compact subset of
Then
Y,
and let
~ ~ ~
~
C
of
Thus for all
2Y<
by
Y.
C
of
x~
F.
S.
Noreover,
~ e w, define
F~(x) = F(x) N Y~
Y<.
~ S~
for each
Further
F~(x)
and
x~,
f " X --~ Y
Y<
S~
for
by
C
f'l(c) ~ S
for
be a compact subset
be an at most countable ordinal such that
FsI(c ) C
is
~ • w.
~urthermore,
For, let
f~l(c)¢
implies that,
fjl(c N Y s ) C
is the
Thus by theorem 5.1, for each
~ow define
if
X~
is, in
~.
F~I(c) = X< ~F-I(c)
closed (and therefore compact) subset
we have an
since
S~
the
X~, we have that
x ~ X~.
F~ : X~ -~
Each
is a n ember of
Note that, by the definition of F(x) (AY~ ~ ~
X~.
X~
{ F-I(Y<) - F'I(y~) ". ~ • ~ }
F-I(Y~), ~ _< ~,
E S, we have that
are
Assign to each
X~ ~ S<),
intersection of the countable family
X~'s
kJ { F~I(Y r) : r_~ ~ } = @,
55 since
r i ~ < B
implies that
F~l (Yr) = I[ x~ Xs : F~(x) m Y r # ~ } < { x
It follows that
: F(x)
Yr
X
F-l(Yr ) -
f-l(c) --h9 ~ f~l (C /bye) • 6 ~ ~( } •
f~l(C ~ y~) 8 S~ C S
for all
~ _~ ~ .
Hence
Plainly
f-l(c) s S
and thus
the proof is complete. Proof of theorem 8.2 :
Let
¢ " P --~ Y
be a
I-i
function from a complete separable metric space Define
F,. X --~ P
by
F, = ¢-I o F.
is continuous.
Moreover
for every
G
For let
P.
P
onto
Y.
F~(x) is closed for each
x ~ X, since $
open in
continuous
~ x : F,(x) ~ G ~ ~ ) e S G
be open in
P.
Then
G
has a compatible metric which makes it a complete metric space. Hence, the subspace conclude that
¢(G)
G
open in
for
F
Y
is a Lusin space.
¢(G) is a Borel subset of
F~ I (G) = F - I ( ¢ ( G ) ) f, : X -~ P
of
~ S.
such that P.
Define
Y.
Hence we can
It follows that
Applying theorem 5.1, we have an
f,(x) ~ F~(x)
and
f -- ¢ o f, " X -~ Y.
fil(G) e S Then
f
for every is a selector
since f(x) = ¢(f,(x)) ¢ $(F~(x)) = $ o $-ICF(x)) = F(x) To prove that
f-l(s) ~ S
for every
x s X.
B
it is sufficient to prove
set
in
Y, B
in
Y.
Thus, suppose that
is open by the continuity of
¢, and
for every Borel set
f-l(B) s S B
is open in
for every open Y.
Then
$-I(B)
f-l(B)-- f~1(¢-l(B))~ S and
thus the proof of the theorem is complete.
56 Remark 5.3 •
Theorem 8.3 generalises a theorem of Castaing [i]
where he assumes
X
to be a compact metric space and
S
the
corresponding family of Borel sets. We shall end thls section by stating one more selection theorem due to Jacobs [3]. X
For this we need some terminology.
be a complete separable metric space.
Radon measure defined on a compact metric space.
Let
continuous in
x
for every fixed that
f " T ~
X-~
T 2 space Y
for every fixed x.
Let
with t
y ". T --~ Y
y(t) ¢ f(t,X) for every
t
Let
~ T
Let
denote a positive and let
Y
be a
f(t,. ) locally uniformly
and
f(., x) measurable in
t
be a measurable mapping such
and
F
:
T -~ 2 X
denotes the
mapping defined by
g(t) = ~ x " x s X
and
f(t,x) = y(t) }
Now we are set to state our final theorem of this section. Theorem 5.4 ." Under the assumptions stated in the above paragraph, there exists a measurable function x(t) ~
V(t)
for each
t ~ T.
x :
T -~
X
such that
For a proof refer to Jacobs [3].
57 REFEREN CE3
[i]
C. Castaing,
Quelques problems de measurabilite lies a la
theorie de la commande,
C-~- Acad. Sci. Paris
262 [1966], 409-411.
[2]
C. J. Himmelberg
and
F. S. Van Vleck,
Some selection
theorems for measurable f~mctions, Canadian. Mat h
[3]
Marc.
Q.
21
[1969], 394-299.
Jacobs,
Remarks on some recent extentions of
Filippov's implicit functions le~ma,
5 [1967],
[4]
selectors,
13
SIAM. _J. _ ~
622-627.
K. Kuratowski and C. ~yll-Nardzewski,
Sciences
Jour.
Bulletin
A general theorem on
De L'aAcademl Polonaise Des
(Serie des sciences math. astr. et phys)
[1965], 39?-403.
6.
TWO APPLICATIONS OF MEASORABLE SELECTIONS
In this section we shall give two applications of measurable selection theorems (which we have proved in section S).
The first
result is an example of a non-analytic (in fact non-Lebesgue measurable) subset of Michael Orkin [3B.
[o, IB which is a Blackwell space, due to
The second result is a theorem on stochastic
[4].
games
We will start with some preliminaries. Definition " set
X
A countably generated ~-algebra ~
of subsets of a
is called a Blackwell space if every countably generated
a-algebra ~ C
~
~,
=~.
that is, ~
having the same atoms as
~
coincides with
In [I] Blackwell proved that every analytic subset of a Polish space (endowed with the relative Borel a-field) is a Blackwell space.
We shall now construct an example of a non-
analytic subset of [0, I] which is a Black,ell space. The construction • Borel sets of a set
A c
I. I
al)
Neither
a2)
If
such that exists
f
Let
I = [0, I].
be the a-field of
Using transfinite induction, we will construct
with the following properties . A
nor
Ac
contains an uncountable analytic set.
is a countable to one Borel function from
Sf = ~ x " f(x) • x }
x ~ A
Let ~
such that
f(x) ~ A
We proceed with the construction. of uncountable Borel sets in
I.
I -9 I
is uncountable then there and
f(x) ~ x.
We first well-order the class (This class has power c).
We
next well-order the class of all Borel functions which satisfy the following conditions.
59 f I)
f
is countable to one, that is
countable for every f 2)
Sf
~ f-l(x)}
x.
is uncountable where
Sf = ~ x : f(x) # x).
This class of functions also has power
c.
t~o disjoint collections of nested sets We select distinct points
We inductively construct
~,
E~
[Here
fl
fl(rl) -- s I.
We let
as follows.
Xl' Yl s B! (the first uncountable
Borel set in our ordering) and distinct points such that
~
rl, s I e I- ~xl-Yl)
-- ~x!' rl' Sl}'
is the first function in our ordering.
are reached in our inductive procedure (where we select
x~, y~
from
B~-
~[-J<< ( 4 U
such that
r<, s~
f< (r<) = s<.
from
I
-
~ BU<<
A
=
We can do this c.
We also select
~x<, y~} }
< c, and by noting the
f<, including the fact that
k~# ~ < c
c c),
We can do this by observing that the set of
able and Borel, must also have power
We then let
B~, f~,
is an ordinal
(4 U EB) ~
points we have thus far removed has power conditions imposed on
E1 = ~ Y! }"
When
~
E~).
because every uncountable Borel set has power distinct points
is at most
c.
Sf , being uncount-
We then let
~.
By the method of construction,
4
Ae
(complement of
A)
do
not contain uncountable Borel sets, hence no uncountable analytic sets, so condition (a I) is satisfied. satisfying
Also any Borel function
(f I) and (f 2) appeared somewhere in the induction
process so (a 2) is satisfied.
f
60 We now consider the pair ( 4 Borel
G-field on
A, that is,
~)
where ~ *
is the relative
~3" -- sets of the f o ~
B ~
A,
B~. Theorem 6.1 : ~(on
A)
If ~ *
is a countably generated subfield of
whose atoms (on A) are the points of
4
then
~*
= ~
*.
[Here we assume the continuum Hypothesis]. We need .the following selection theorem due to Proposition 6.1 "
Let
f " Z -~ W
to one function where spaces. (i)
and
W
be a Borel measurable countable are Bore! subsets of some Polish
Then there exists a Borel subset
f~E
Proof:
Z
is
I-I and
Note that if
(ii) f
E. A. Stchegolkow.
f(E)
E
of
= range of
Z
such that
f.
is a countable to one continuous function
defined on a complete separable metric space taking values in a Polish space then the forward image of every Borel set is also Borel - for a proof of this see Kuratows~i, It is er~ugh to prove proposition 6.1 countable to one and
Topology Vol I. when
f
is continuous,
Z = N N ( = the set of all sequences of positive
integers. Let
X
subsets of Plainly
= range of Z),
f.
such that,
Define F:X--> ~Z (nonempty closed F(x) = f-l(x).
F(x) is clo~ed for each
x
since
f
is continuous.
F
is also measurable since, the set,
iS Borel (by the remark made above) for every open set
U
in
Hence by Karatowski --Ryll-Nardzewski's
F
has a
selection
g.
That is,
g " X -~ Z
theorem
(5.1).
is Borel measurable and
Z.
61
g(x) z F(x) = f-l(x) for every E = g(X).
Then
proposition
E
Plainly
g
is
I-I.
Take
has all required properties stated in
6.1.
Proof of theorem 6.1 : class for
x.
~
by the sets
Let
Fn = B n ~ A
be a countable generating
and consider the sub-~-field of ~ Bn.
Call this
~-field ~ .
on
I
generated
We claim the atoms of
are countable sets. If T
T
is an atom of ~ ,
since
contains at most one point in
( ~
separates points on
A,
Since
T
is a Borel set
being countably generated) and because
T
contains at most
one point of set for
Ac
A,
T ~ Ac
A.
~
is Borel.
Thus
T
#I Ac
contains no uncountable Borel set.
is a countable
Thus
T
is a
countable set. We now use the Borel selection theorem, that is proposition 6.1. g
This proposition implies the existence of a Borel function
from
I -~ I
which maps each atom of ~ onto a point in itself.
Since the atoms of one.
~
are countable sets, g
[See the remark 6.1 below].
is countable.
Indeed if
S
We clai~
must be countable to Sg = ~ x : g(x) # x }
is uncountable, then
g
g
the class of functions we used in the construction of must exist distinct points impossible since of
~
g
x,y ~ A
~ith
belongs to 4
g(x) = y.
and there
This is
maps each atom of ~ into itself and no atom
contains more than one
A
point.
But the fact that
S
g countable implies that all but a countable n~Eber of the atoms of ~
are singletons.
Thus ~
separates the points of
exception of at most a countable set. =
.
I
with the
From this it follows that
Thus the proof of theorem 6.1 is complete.
is
62
Remark 6.1 .
Our use of the selection theorem was accomplished by
using the well-kno~n fact that if ~ a-field on
is a countably generated
I, say, then there is a Borel function
f
which maps
distinct atoms into distinct points (not necessarily in the same atom) and from wkich ~ through
can be got by mapping the Borel sets of
f-I (for example, if
FI, F2,... , generate
~
,
I
let
Oo
f
=
Z n=l
2fn 3n "
where
fn(X) = I
If we consider the graph of
f,
if
x e Fn
and=O
if x ~ Fn).
which is a Borel set in the
corresponding product space, the horizontal sections of the graph correspond to the atoms of
~.
Since in the case, we were
considering, these sections were then countable sets, the conditions for the selection theorem were satisfied and the selection function so obtained mapped each atom of %
onto a point in itself.
Before stating our next result on stochastic games, we shall write down our assumptions. stochastic games]. A
and
B
S
will be a complete separable metric space.
are finite sets
function of
s
[See section4 for details regarding
for fixed
r(s, a, b) is a bounded measurable a, b.
Now we shall state our theorem [4].
TheoreE 6.~ : Under the assumptions stated above, the stochastic game has a value and the value function is Borel measurable. more Players I and II have optimal stationary strategies. R
~
:
Let
rw
:
S-->
PA ~
PB
where
rwCs) = ~[ (~',x') : max [r(s,s,~,') + ~ f w(-) dq(. Is,~,X')] = rain [r(s,t~',X) + ~ I w(.) dq(. Is,#',X)} k
Further-
63 and
w
is a bounded real-valued Borel measurable
These set valued functions Olech [2]. theorem 6.2.
rw
function on
S.
are measurable by a result of
Now one can use (the selection)
theorem 5.3 to prove
The rest of the proof follows along similar lines
to that of theorem 4.2, -with some minor ,~difications the proof of theorem 6.2 is omitted.
and hence
64 REFERENCES
[1]
D. Blackwell,
On a class of probability spaces, Proceedings
of the third Berkeley Symposium on Mathematical Statistics and Probability Vol 2, p 1-6, edited by J. Neyman, University of California Press [1956].
[2]
C. Olech,
A note concerning set valued measurable functions,
Bulletin De L'Academie Polonaise Des Sciences, S _ ~ ~e~ S i e ~ ,
[3]
M. Orkin,
~.ath, ~s~ro et Pl~vs. 13 [1965], 317-321.
A Blackwell space which is not analytic,
To appear.
[4]
T. Parthasarathy, Discounted and positive stochastic games, Bull. Amer, Math. Soc
77 [1971], iS4-136.
7.
VON-NEUMANN'S
MEASURABLE CHOICE THEOREM
The purpose of this section is to prove a measurable theorem due to von-Neumann.
choice
After giving the proof, we shall
mention a few consequences of this theorem. Choice Theorem 7.1 [4] ". Let
S
be a complete separable metric
space,
S
and
A
an analytic set in
defined and continuous for all values.
Let
assumes.
K
Let
A
and has real numerical
be the set of all values, which ~ (k)
is a monotone,
a ~
F(a) a function which is
be an arbitrary
nondecreasing,
F(a), a c A
N-function,
rlght-continuous,
that is,
T (k)
bounded function.
Under these assumptions we have (i)
K
is a
T (k)
measurable set.
(ii)
there exists a function
X ~ K
and assumes values in (a)
k ~ K
If
with (b)
Proof :
0
S
such that
is an open subset of
f(k) c 0 For every
is
S, then the set of all
"[ (X)-measurable.
k ~ K,
F(f(k)) = ~.
We shall prove the theorem when
and nowhere constant
~-i~anction,
a topological mapping of a ~ ~ • b
f(k), which is defined for all
where
a
=
T (k)
therefore
is a continuous
k -~ % (k) = ~
is
- co ~ k ~ oo on the finite interval T~(- co),
b
= p~(+ co).
The general
situation can be reduced to this case [4]. Let us now replace and then write again
X
F(a), f(k) by for
our assertions unaffected, ~.
The domain of
k
~.
(F(a)),
f("C-I(~)),
This leaves the structure of
but there are these changes regarding
is now
a
~ k • b
and
not
- oc ~ k • + co.
66 In this new domain we have to use the notion of common (Legesgue)measurability and not that one of T(k)-measurability. -9 I~(k)
[Our mapping
transformed the latter into the former].
We now introduce the '0 space of Baire', So, which is the set of all sequences
4 = (n!,n 2 .... ),
nl, n 2 ... = 1,2, . . . .
It is metrized by the definition Dist [(ml,m2,...) , (nl,n2,...)] = u
if
mv = nv
= _I_ if
vo
vo
for every
is the smallest
integer for which
Thus
SO
is a complete, separable metric space.
set of all those
~ = (nl, n2, ...), for which
a finite number of
vo
exists such that
mvo • %
establishes an ordering of all
~ ~ 4
we have sphere in 41, 42) . then
is open.
~ < 4 So
[The countable nv W i
occurs for
If
So.
(ml, m2,...) • (hi,n2,...) and If
p ~ 4, and
in the entire sphere is a set of the form
mv ~
= nv
for
P -- (nl, n2,...)
if a
is fixed, then the set of vo
is defined as above, then
Dist (~, B) • I/v o. ~l -< ~ ~ 42
Every
(with fixed ¢ ~ O,
belongs to it, if and only if,
Dist ~ (ml,m2,...) ' (nl, n2,... ) } < ~, where
So] .
v < vo ,
If its center is (ml, m2, ...) and its radius
v = 1,2, ..., v I
m v W nv.
v's only is obviously everywhere dense in
On the other hand the definition,
v.
vI
may be written in the form
that is
m v = nv
is the greatest integer
for
_< i/~.
This
~I -< p ~ c(2 if we put
~I = (ml'''',mVl-l, mvl, I, I, ...), ~2 =(ml,"',mVl-l, mvl+l,l,l, --~-
67 As
A
Is an analytic set In a complete, separable metric
space, therefore there exists a function and continuous for every
~ ~ So
and ~Lich maps
[The mapping may be many to one]. the set of all
There As
F(~(~)), ~ s So.
continuous for every
~ z So
~(~) which is defined
K
So
onto
A.
Is clearly
F(@(~)) also Is defined and
and the real numbers form a complete,
separable metric space, we can conclude that
K
is an analytic
set and consequently measurable. Consider now a wlth
F(@(~)) = X
k ~ K.
by
Denote by the set of all
T(A).
as
F(@(~)) Is continuous,
nI
with
As T(X)
(n I, n2, ...) ~ T(A)
the smallest
n2
(us, n4, ...)
by
with ~
k ¢ K,
Is closed. for auy
etc.
Let
for every
<(~)=
with
~(A) ~ ~o"
F(@(~)) = ~.
{ B : ~ < ~o ) M( ~ o ) If
~,
... ).
It
and therefore <(X) ~
has a first element,
In
~o
and consider the set
That is, ~ ~ ~o
k e M(~o) wi~h
in other words So
under
M(~o) for all
is clearly equlvalen~
8 ~ T(~), that Is of a ~i(~o)
F o ~ .
is any subset of
Hence
wlth
~(A) ¢ T
by
i~(T),
if
form
~l -< ~ ~ ~2, therefore
result proves therefore, that
So , d e ~ t e T
~ < ~o
is the image of open set we can conclude
is an analytic set and hence measurable. ~
n~,
~(X).
to the existence of a with
T(A)
by
T(%) for ~ y
(n° ' ~ ,
T(X)
In other ~ r d s
Choose now a fixed X's
Denote the smallest
besides its definition guarantees that
~ ~ T(A).
and thls Is
is not empty and
(n2, n3, ... )
(nl, n2, n S . . . ) ~
is clearly a condensation polnt of ~(A) ~ T(A),
T(X)
~ ~ SO
the set of all
A's
Is a sphere, then it has the
i~(T) = M(~2) - M(~l)" ~(f) is measurable.
Our above If
T
is
68 merely an open set, then, as
So
is separable, we can write
T
CO
as the sum of a sequence of spheres : T = ~ Ti. NOw co i--I N(T) -- ~_# N(TI) , and as ~N(Ti) } are all measurable, so is i=l
Let finally
O
be an open subset of
the set of all
c( ~ SO
is continuous,
therefore
measurable.
That is,
with
~(~) ~ O.
S,
As
0
T(O) is open too.
X s N(T(O))
means
and denote by is open and Thus
~(T(O))
~(X) z T(O)
T(O) #(c() is
and hence
~(~(~)) ~ 0. Observe finally, that as
The measurability of
K
~(X) ~ T(A) (assuming
A ~ K),
being already established, we have
proved statement (1) of our theorem.
And in order to prove
statement (ll) it suffices to define
f(A) = #(~(A)).
Thus the
proof of theorem 7.I is complete. For the statement of our next theoreE we need some definitions. We shall need the concept of standard measurable space.
This is
a measurable space that is isomorphic to a cartesian product of {0,I} points
countably many times. O
and
1
The space
~U,I}
consists of the
only and all subsets are measurable.
An isomor-
phism between two measurable spaces is a one-one function from one onto the other, that takes measurable sets onto measurable sets in both directions.
The unit interval, any Euclidean space, and in
fact any uncountable Borel subset of shy separable complete metric space, with the usual Borel a-field, is standard, to state a theorem due to As/mann [i].
i~ow we are ready
69 Theorem 7.._._..______"_~2 Let (T, ~)
be a ~-flnite measure space, let
a standard measurable space, T ~X
whose projection on
and let £
is
(bebesgue) measurable function for almost all
t
in
set is measurable Remark 7,1"
be a measurable subset of
all o f
T.
Then there is a
g " T --~ X, such that
(t,g(t)) ~ G
~-measure
OJ.
This theorem follows from the previous theorem --for
requirement that
Also, X
shows.
the theorem is false without the
be standard, Let
the Borel sets, and let subspace Qf
be
['ALmost all' means that the exceptional
and of
a proof refer L1].
Lindenstrauss
T.
G
X
as the following example due to
T be the half open interval ~
be Lebesgue measure.
Let
[O,1 ) with X
be the
[O,1 ) that one usually uses to show that there are
non-Lebesgue measurable sets, that is, the sets mutually disjoint for rational (addition is modulo 1).
bet
r, D
and
X + r
are
k J ( X + r) = LU, l> r
be the subset of
T ~X
defined
by
D=
((t,
•
Here
D
is a sort of diagonal of
that
D
is measurable ; one builds a fi~zlte n~mber of s~all
rectangles whose union covers and the intersection is X
exhausts
X,
D.
T ~X°
D, lets the rectangles get smaller, Note that the projection of
but the projection on
in fact, the projection is precisely a subset of Let
~. G
It is not hard to check
= k_3 (D + (r, 0)). r
D
I' does not exhaust X,
on T ,
which may be considered
70 Clearly
D + (r, O)
The projection of projection of
G
is measurable, D + (r, O) on
exhausts
follows that for each such that
t
(t,g(t)) ~ G.
T.
and hence
~
is
G
Is measurable.
X + r, and hence the
Since the
X + r
are disjoint,
there is precisely one point
0
S + r -- S
If
S
for all rational
r, then
~(S)
> O.
which
1 :
hence for every
has density
ly small interval
is, t)
around
~(S ~ Is, t)) ~ ~-~) (t-s).
and
to, ~
or
s
1.
to
at
and every sufficient-
will have
In particular,
~(S ~ Is, t))
~(S) = o
T
Then we can find a point
if
m
large positive integer, we can find an interval t - s -- i/m
on a set
is a measurable subset of
£o prove thls suppose S
g
only.
We first prove a lemma : such that
g(t) ~ X
Clearly it is sufficient to prove that
there is no measurable function that differs from of Lebesgue measure
It
• (1-~)/m.
is a sufficiently ~s,t) such that
i~en
m
~(s)
= ~ ( s ,u Co, l } )
= ~ ( s r~ z (Ls, t ) + J/m)) J=l
m
=
z
~(s~([s,t)
+ J/m))
J=l =
m 7. ~ ( ( S + J/m)
(h (Is, t) + j/m))
J=l m
=
Z
~ ( ( S rh [s,t))
+ J/m)
J=l m
=
Z
~z(S ~ is,t))
> m(l-~)/m
= 1 - e.
J=l
Since
~
may be chosen arbitrarily small,
the lemma follows.
thls lemma we deduce the following Corollary.
If
S
is a not
From
71 necessarily measurable subset of all rational
r,
Indeed, let
take
S'
then the outer measure of
S'
~(S') -- ~+(S),
where
~+
by
and includes
S,
denotes outer measure.
S + r
=
= s+(S). I
S.
S ;
Now
or
Then
S' + r
S'' + r
S"
S'' C =
0
or
{ Si } Si
= ~S'
S'
S"
I.
(For example, of measurdiffers
is measurable for all
Therefore
since
for
such that
such that the measure of
i/i).
able, and includes
~(S'') = O
S,
S + r = S
is either
to be the intersection of a sequence
~+ (S)
~(S")
S
be a measurable set containing
able sets containing from
[o,i) such that
+ r
r,
is measur-
it follows that
for all rational
r,
hence
and the Corollary is proved.
Obviously the outer measure of a measurable subset of
T
such that
X
cannot vanish; Y ~ X
and
let
Y
be
%z(Y) = N+(X) • 0.
Using density considerations as in the proof of the lemma~ we can find t%~ dlsJoin5 intervals such that
~(Y ChIl) , 0,
~+(X C~ 12) • O.
I 1 = [Sl, ti) ~(y c3 I2) • u.
and
12 =
Then also
Is2, to) ~+(X ~ I I) ~ 0,
Let xI
--
<3
( ( x ~ I l) + r)
r
LJ ((X fhi2) + r). r
Then XID
X1 + rI X rill,
-- X 1 and
and
X 2 + r -- X 2
~+(X l) _ ~ + ( X
~ I I) • 0 ~
So from the Corollary it follows that and since
~
where
denotes the inner measure.
~-
~
X 2 = g,
for all rational
Iz+(X1 ) = i,
it follows that
N'(~)
But
follows that there is no measurable function differs from example.
g'
similarly
on a set of measure zero.
r.
But
~+(X 23 ~ O.
~+(X 2) = l,
= N-(X2) = O,
X 1 = g-!(ll) , and it g'
such that
g
l~lis completeshhe
72 We shall present another version of von-Neumann's choice theorem.
Let
X
The function
F
will be defined on
be subsets of X
be an arbitrary complete separable metric space.
X.
T = [O,1]
Recall a point valued function
will be called Lebesgue measurable if
measurable subset of subset of
X.
T
X.
f-l(u)
f
from
T
to
Is a Lebesgue
for every open (or equivalently, Borel)
An analytic subset of
a Borel subset of
but its values will
X
is the continuous image of
The set-valued function
F
will be called
analytic if its graph, that is,
(t, u ) "
is an analytic subset of
Proposition 7.1 ; to
T x X.
Now we have the following
[2].
proposition
T
u ~ F(t) )
If
F
is an analytic set-valued function from
X, then there is a Lebesgue measurable point-valued function
f " T -~ X
such that
f(t) ~ F(t)
for almost all
t.
Proof follows from theorem 7.1. Next we give an application of proposition 7.1
in the
characterisation of extreme points of sets of vector functions [2,3]. Let
A
be a compact convex subset of
extreme points,
~
the closure of
B.
Let
En,
B
MA,
MB
the set of its and
M
be B
the sets of all measurable functions from B
respectively.
T
to
En
T = [0,I]
to
A,
B
Since the space of all measurable ftuuctions from
has a linear structure, it is meaningful to talk about
the extreme points of Proposition 7.2 "
and
MA.
The set of extreme points of
MA
is precisely
73 Proof :
Clearly every point of
Conversely, let MB,
f
t
t,
f(t) = 12 g(t) + 12 h(t), t.
g(t)
and
and
g(t)
h(t)
and
and
f
If
in
h(t)
f
A
= ~2 g + 21 h,
M A-
is not in A.
Hence
so that
differ from f(t ) for
Because of proposition 7.1,
chosen so as to be measurable as well. MA
N A.
f(t) is not an extreme point of
we may choose
at least some
is an extreme point of
be an extreme point of
then for some
for each
PB
Then
g g
and and
h
h
may be are in
contradicting ~he extreme property of
f.
This proves the proposition. Another situation treated by Karlin [8] is the following. Let
IZl' ~2, " " , ~m
on
T,
and
B
and let
be a set of non-atomic totally finite measures
aI, ..., am
be as above.
that
Let
b i _~ ~ f d Ni --~ ai
the extreme points of
G
and
bl,...,b m
PrOof :
for
i = !,~,...,E.
are contained in
The extreme points of
G
and suppose
in the previous proof, and let f + e
=
g e MA
and
~(S) = ~ S~[ e d ~!' of dimension
m.
for
on
T
t @ S.
by
e = !2
g
= h ~ M A.
f
be an
Construct
g
and
For N
such
We shall now
are contained in
h
Then
f
Let
-
A
Karlin proved that
N . B
G
f g MB.
... ' SI e d N m }.
M B.
h
so that S C T
set
is a vector measure
Applying Lyapunov's theoreE on vector measures,
we obtain a subset e'
f - e
Let
MA, consiting of functions
We follow the proof due to Aumann [2].
extreme point of
En.
G
prove the following proposition. Proposition 7.~ :
be in
S
e'(t) Define
of
T
= e(t)
such that for
fl = f + e',
t s
~(S) = ! ~(T), S,
f2 = f-e'.
and
Define
e'(t) = -e(t)
Then
as
~D
o~ O
~J
0
I-*
~D
~D
II
I-b
P.
H~
H
7~
~D
!
tu,
÷
!
7~
i~ .
II
i-J
~o
r
I!
75 REFERENCES
[i]
R. J. Anmann, theorem,
Measurable utility and the measurable choice Proc. Int. Colloq., La Decision, C.N.R.S,
Aix- e n - Provence [1967],
[2]
R. J. 2amann,
15-26.
Integrals of set-valued functions,
Math. Analy. Appl. 12 [1965],
[3]
S. Karlin, F~th. Soc.
[4]
M~th.
1-!2.
Extreme points of vector functions,
~.
~er.
4 [1958], 603-610.
J. yon Net,nann, ~.
Jour.
On rings of operators, Reduction theory,
50 [1949],
pp
448-451.
8.
ON THE UNIFORMISATIO~ OF SEfS IN TOPOLOGICAL SPACES
Given a set spaces
X
and
projections X
E
in the cartesian product
Y , a set
~X E
and
U
~X U
of
{(x) × Y } U
E
and
x ~ ~X E
if
E E
through
Y
x
But, If
if the onto
the set
...
(1)
consists of a single point.
existence of such a uniformising set
and
U
E,
~
lying above
the axiom of choice.
of two
is said to uniformlse
coincide, and if, for each
of points of
X ~Y
X
and
U Y
The
follows immediately from are topological spaces
is, in some sense topologically respectable, for example belongs to some Borel class, it is natural to ask a
uniformising set not much ~ r s e .
U
that is equally respectable or at any rate
Usually there is no way of controlling the
topological respectability of sets obtained by the use of axiom of choice and quite different methods have to be used in obtaining topologically respectable uniformising sets. The earlier work of Lusin [3] on problems of this nah~re was confined to the case when for each points of
E
lying above
x
x
in
~ X E, the set (I) of
is at most countable.
The first
general result seems to have been the result obtained independently by Lusin [4] and Sierpinskl [7] showing that, are Euclidean spaces and unlformising set analytic set.
U
E
Is a Borel set in
when
X
X ~< Y,
and
Y
the
can be taken to be the complement of an
Following work by Lusin and Novikoff [6]
on the
effective choice of a point from a complement of an analytic set
77
defined by a given sieve, Kondo [6] sho~,~ed that in the Euclidean case, the complement of an analytic set could be unlformlsed by a complement of an analytic set.
Since any Borel set in a
Euclidean space is the complement of an analytic set this provided a most satisfactory generallsation of the result of Lusin and Sierpinski. closed set
Braun L2] showed in the ~uclidean plane that any E
can be unlformised by a
set can be uniformised by a
G~
G~
set and that any
F~
set.
It is easy to extend the results of Lusin and Sierpinski and of Kondo when
X
and
Y
are complete separable metric
spaces by the following mapping technique.
If
X
is a complete
separable metric space there will be a continuous function that maps a relatively closed subset irrational numbers in onto
X.
[0, I]
[0, I]
J
o
of the set
Y.
Then the product map
continuously and one-one onto
f-I ~ g - I
of ~,
X ~Y.
Borel sets and coanalytic sets in Lusin and Sierpinski or of
Io x
R 1 ~<S I.
back to
X ~Y
there results in
g
that
S1
of real maps
Hence the inverse in
X ~
Y
J o, which remain So the results of
Kondo can be applied in
when the unlformising set is intersected with
one-one
of irrational
f X g
maps Borel sets and coanalytic sets
into Borel sets and coanalytlc sets ia
f Xg
J
regarded as a subset of the set
numbers, one-one onto
by
I
Similarly there will be a continuous function
numbers in
map
of the set
regarded as a subset of
maps a relatively closed subset
Io x J 0
I0
f
R 1 ~( S 1
I0 x J 0 X xy
and mapped
a uniformising
set that is the complement of an analytic set as required.
We shall
now prove the following theorem due to Rogers &nd Willmott [6].
78
Theo~
8.1 ". Let
X
be any topological space.
q-compact metric space.
Let
~
can be unlformised by a
can be uniformised by a
X ~Y,
be any
D6
Then a closed set in
set and a
Fq set in
X ,~Y
D~-set.
We will now introduce some notations we study a cartesian product ~y
Y
be the family of finite unions
of differences of closed sets in X ~Y
Let
X xy
and definitions.
When
of two spaces we use
to denote the projection operators onto
X
and
Y
~X'
respective-
ly, so that ~x(X ~ y ) If
C
= x,
is any set in in
~y(X ~ y )
X ~Y
Y
= y
we use
with
for
x ~ X, y ¢ Y.
C (x), for
x "
and
x ~ X, to denote
the set of
y
C (y) is defined
similarly.
We also define the cylinder on a set
E
to be the
set ~xEX and use A set U C x
in
cy E U
E,
Y
to denote the cylinder.
will be said to tuliformlse a set ~X U = ~X E
and
U (x)
E
in
X ~(Y
if
contains a single point for each
~ X E.
A function
f
is defined on
is said to uniformise ~X E
into
x ~f(x) We will call a set it is of the form
Z
~ E in
Z -- P ~ Y
Y
a set
E
in
X ~
Y
if
f
so that
for every X ~Y
x ¢ ~ X E.
a cylinder parallel to
for some subset
P
of
X.
Y
if
79 Lemma 8.1 :
Let
Y*
be a compact subset of a
J
be a set of the form
Z
a closed cylinder parallel to
j
o
Jl
F - Z
n
Let
Y.
=
J - cy Jo
(x
J
~
closed
and
and
@
~ X Jo k] ~ X Jl
=
~ X J"
F
closed and
Z
a closed cylinder
Then
Y-}
is of the required form, as
F
: {Fn(X×Y*)}-z
f~ (X ~
it follows easily that
closed set in
F
Y~)
=
with
with
Let
Y.
Then the sets
V X Jo C~ ~ X Jl
Jo:{F-z}n{x
is compact,
Y.
J
J = F - Z
parallel to
X "< Y
=
are both of the same form as
Proof "
in
T 2 space
X.
~ X { F C~ (X x
Y*)]-- [ ~ X {
is a closed cylinder parallel to
J1-- J - c y
is closed. y*)}
As
Y~
is a
Hence the set
zI -- cy [ F ~ ( X ×
°YJo--°Y[
Y*)
{Fn(×~
Jo
Y.
F:~(X~
Further
y-)}. z] -- ~ -
: {F'z}-{Zl'Z} =
F-
(Z<2
Y*)] ] × Y
~)
z
8O and
Jl
has the required form.
The formulae for the intersection and union of the projections of
Jo
and
J1
a subset of
J
follow immediately from the facts that and that
J! = J - cy Jo"
Proof of theorem 8.1 :
Let
E
Y
be a closed in
with the properties
(a)
the diameter of
(b)
each point of
Yi Y
is
This proves the lemma. X x
is a-compact and metric, we can choose a sequence of compact subsets of
Jo
y.
As
Y
YI' Y2 "'"
:
tends to zero as
i -~
co
and
belongs to infinitely many sets of
the sequence. We define sets
Do, DI, D2,
Dn+ I = ~ D n n
...
inductively by tsking
(X "( Y n + l ) } k # ~
Dn - c y ( D n ~
Do = E,
(X ~ Y n + l ) ) }
...
for
n = 0,1,2,
lemma that with
F
Dn
....
It follows inductively,
is the union of
closed and
Z
2n
sets,
by the use of the
each of the form
a closed cylinder parallel to
disjoint projections with union
(2)
Y,
F - Z having
~ X E.
Co
Write
U
Then each set
=
Dn ~ ~
~X U
~ n--O
Dn .
and
U
is a
?TX Do
~ I ) ~ set.
= ?TX E
it will suffice to show that given any point
Yx
with
x "~ Yx ~
As
U.
x e ~X E, there is a unique
81
If
x c ~X E,
the set
D (x)
=
o
E (x)
Our aim is to show that the sets
is closed and nonempty.
D n(x) ,
n = 0 , _ , _ ~. ,l
closed, decreasing, nonempty, compact for and w i t h d i a m e t e r
set
u(x) =
tending
~ n=o
Dn(x)
to zero.
n
..., are
sufficiently large
This ~'~ll e n s u r e t h a t
the
consists of a single point as required.
It follows from (2) that,
Dn+l( X=) D(X) n =
for
Dn(X)
n = 0,1,2,
n = 0,1,2, ...,
integer
D(X)/hn Yn+l # ¢
D(X) n f~
if
Yn+l
=
It follows immediately that the sets • ""
sequence
if
Yn+l
are closed, decreasing and non-empty.
YI' Y2' "'" n(x),
Dn(x) (x) ~
is compact for
~(x) I)n t
"
covers
Y,
Yn(x)+l
n _~ n(x) + I.
As the
it follows that for some first # @'
This implies that
As each point of
infinitely many sets of the sequence
Y
YI, Y2' ...,
D (x) n
lies in and as the
diameters of these sets tend to zero, it follows that the diameter of E
D(X)n also
-90.
This completes the proof of the case when
is closed. ~Dw consider the case when
~-compact we can express each set
En
compact set in
E
E
is s/1 F
in the form
is closed ~nd each set Y.
Then each set
E
~ y En
~ X En
set. ~s Y is co = i_J ~ , where n=l is a subset of a
is closed (being
effectively the projection of a closed set through a compact space). Let
Un
be a
D~
set unlformlslng
~,
for
n = !, 2, . . . .
82 oo
Let
J
=
n
/-] m=l
Dnm
D
where each set
~ ~
.
It is clear
that the set
U
uniformises
--
E.
u
L # [ Un - cY ( U n=l v
)]
But oO
u
As
~X
E
n
ey(
-
u
u
-~
)
m= I
is closed for
Dnm
--
~
- cy
(
~
n, the set
<
U
E
)
w
belongs to ~ .
Remark 8.1 :
Hence
U
is a
_D~
If each open set in
~
-set as required.
is a
F
ising set for a closed set can be taken to be a for a
F~
set can be taken to be a
as follows.
and
V
in
X xy
is an
is a
G~
-set.
In this case each open set in
union of open rectangles X
G~
X
and
F~-set.
set in
U ~ V
in
V. Y
~hen, is an
X ~
set, the uniformG~
set and that
This can be seen Y
is a countable
as each open set F~-set,
in
each open set in
So each closed set and hence each set
X "~Y.
U
im
The result follows.
We shall close this section after stating one more result due to Rogers and Willmott, Theorem 8.2 : X
a proof of which can be found in [6].
Suppose that each open set in a topological space
is a Souslin set.
Let
E
be the complement of a Souslin set
83 in
X ~
I
where
I = [0,I].
Then there is a set
the complement of a Souslln set in
(a)
u
(b)
~X U
(c)
for each
X ~(I
U, that is
and that satisfies,
~n E
=
~X E
and
x ~ ~X E, the set (~x} ~
I)
f~ U
contains a single point.
Remark 8 . 2
;
It seems that Robert ~olovay has proved the
following result
LSee L8], Remark 4, pp 2]
existence of measurable cardinals.
assuming the
Every complement of an
analytic set in t~o-dimensional Euclidean plane can be unlformised by a Lebesgue measurable set of
~I] in this connexion.
:
See also
pp
24-25,
84 REFERENCES
[i]
R.J.
;mmann,
Measurable utility and the measurable
choice theorem,
Proc. Int. Colloq., La Decision,
C.N.R.S., Aix-en-Provence [1957], 15-26. [2]
S. Braun, Sur l'uniformisation des ensembles fermes, Fund. Math, 28 [1937], 214-218.
[3]
N. Lusin, Lecons sur les ensembles analytlques et leurs applications.
[4]
N. Lusin,
Paris, [19:30].
Sur le probleme de
tlon des ensembles. [5]
N. Lusln and
M.J. Hadamard d'uniformisa-
Nathematiea, 4 [19S0], 54-66.
P. Novikoff,
Choix effectlf d'un point
dans un complementaire analytic arbitraire, donne par un erible, [6]
Fund. M_aJ~, 25 [1935], 559-560.
C. A. Rogers and R. C. Wi!Imott, sets in topological spaces,
On the uniformisation of ~.
~
120 [1968],
1-52. [7]
W. Sierpinskl,
Sur l'uniformisation des ensembles
measurables (B), [8]
R. Solovay,
Fund. Math
16, [1930],
136-139.
A model of set theorey in which every set
of reals is Lebesgue measurable,
[1970], pp 2.
Ann. ~
92,
9.
SUPPLE~I~NTARY REMARKS ON SELECTION THEOREMS
The purpose of this section is to make a few remarks o n selection
theorems
covered so far.
and to
mention
applications
w h i c h we h a v e
r~t
We may not give detailed proof to any of the
theorems to be stated in this section but we give references where one can find the complete proof. (a) @
n-selections
Suppose
be a function from
2Y X
:
X
and
Y
each
2Y
~(x)
points and
~ :
is a subset of
• ~(x) x~X
a topology of when
2Y
to
X -~ 2 Y
Definition :
@(x)
is closed in X
A function
kff ~(x). x~ X
is a lower semicontinuous
A carrier
~
is coEpact for each
Ly
from
if for n
In order to relate Y
to that of
function,
X
it is
have the following properties.
@ : X-~
2Y
is said to be point-compact
=
~ x . y ~ @(X) }
y ~ Y.
A carrier will be called small if for each O,
q
Ly (defined below)
Ly
set
~
(Here
containing at most
or the topology of
convenient to require that
if the set
Y).
is said to be an at most n-selection for
x s X,
Let
X -~ 2 Y, sometimes called a carrier.
denotes the set of closed subsets of to
are metric spaces.
c
0 ~
X,
y ~ Y
there is an open neighbourhood
for which
¢)
o.
and open V
of
y
86 Remark 9.1 : $ : X-~
2Y
If
f : Y -• X
defined by
is an open and onto mapping, then
O(x) = f-l(x) is a lower semicontinuous,
small and point compact carrier. semlcontinuous,
X
Also if
is compact and
small and point-compact.
Y
$ " X -~ 2Y is upper
is regular then
$
is
The following theorem has been proved
in [6] by McAuley and Addis. Theorem 9.1 : di= X < n
Suppose
and that
X
and
Y
~ : X -9 2Y
are metric spaces with is a lo~er semlcontinuous, s=all
and point-compact carrier for which to the metric on B
c X
Y
for every
$(x) is complete with respect
x ~ LK.
Furthermore, suppose that
is a closed set (perhaps empty)
map so that
g(x) ~ ~<x)
most (n+l)-selection Re~ark 9 , 2 :
~
for each for
~
and
g : B -9 Y
x ~ B.
is a
Then there is an at
such that
~(x) = g(x) for
x ~ B.
The proof depends on the fact that certain project-
ions are closed mappings (which is not true in general) but our assumptions on (b)
~
ensures that they are closed.
Continuous carriers :
We will now briefly mention about
continuous carriers discussed in [8]. (metric • O, every
P), then a carrier every
xo ~ X
~ : X -~ 2 Y
has a neighbourhood
Y
is a metric space
is continuous if, given U
such that, for
x • U,
$(xo) ~ N~(~(x)),
where
If
~(×) c ~ (~(xo))
N ( $ C x ) ) = ~ y : pCy, #(x)) < ~ }
etc.
It is clear that
is continuous in this sense, if and only if it is continuous,
87 in the usual sense, with respect to the following topology 2Y.
This on
~
2Y
is the topology generated by the uniform structure which is obtained by taking, as a basis for the
entourages of the diagonal in
2Y ~ 2 Y, all classes of the form
= ~(A,B) ° A,B ¢ 2 Y,
~
with
~ ~ O.
A Ci~(B),
~(Y)
a selection.
Y
( = nonempty, closed, convex subsets of If
X
is a topological space, and
open, convex subsets of
Y
~
theorem when
Y
x a X
X
X
Y
Y) admits
normed linear
to the nonempty In these two
except that it is a
X
$
as well as the sets
~(x).
is finite dimensional (here we mean Lebesgue
covering dimension, that is, dim
every
X ~ n
if every finite open
has a finite open refinement
belongs to at most
n + i
~4/ such that
elements of ~L/), it is
possible to place purely topological conditions on the sets
O(x)
which are not only sufficient but, in a sense, also necessary. See [7] in this connexion. (c)
Part metric in convex sets ". ~1ow ~,zewill briefly discuss
some results on the part metric and its relation to selection theorem due to Bauer and Bear. nari es.
is
is an arbitrary metric - of course one has to
X
of
X
It ~ould be nice if one could prove a selection
have strong assumptions on the map For example if
from
admits a selection.
results no restriction is placed on topological space.
If
a Banach space then every continuous
space, then every continuous carrier
covering ~
B • It(A) } ,
Now one can prove the follo~dng results.
a topological space and @ : X -~
~c on
We will start with some prelimi-
88 Consider
a real linear space
which contains no whole llne. is denoted by in
C
by
write
~x, y].
r(> O)
x .~ y
If
If
classes of ~
The closed segment from
x, y a C
~;e say that
x + r(x-y) ~ C
if Ix, y]
that .~ defines
L, and a convex set
and
extends by some
an equivalence
There is a metric on each part of
C, C
x
is not equivalent
satisfies
r • O.
y,
firdte.
write
metric on
C. :
(i)
This metric
A mettle
d
the mapping
[0, I] ~ C ~< C (il)
into
the set
~ ~ 0
on
d
C
C.
~he equivalence
are clearly also convex.
is continuous
and each convex subset
in a position
paracompact ?r
~
of
Let
space
~ T
of
and S) < ~ ~
S
of C
is convex for
C. without any line is Now we are
theorem.
be a lower semicontlnuous
mapping
from a
to the nonempty closed convex subsets o f
of the cone
a locally compact
d
except that it is
C -- for a proof see [2].
to state the following
Theorem 9 , 2 -
C,
Then
will be called convex if
The part metric of a convex set
one part
d(x, y) = + oo.
r }.
will be called the part
~ y : y ¢ C, d(y,
convex on each part
We
It can be shown
(k, x, y) -~ k x + (l-k)y C
y
defined by
all the axioms of a metric on
not always
each
to
to
L
Ix, y] extends
d(x,y) = inf ~ log(l + I) r : L~x ,~J "~ extends by
If
x
in
y + r(y-x) ~ C.
relation in
, called the parts o f
C
space
M+(X) of nonnegative X.
Then there exists
Radon measures on a continuous
89 selection for f
#.
has the form
mapping from
T
Let
f
be any such function and
f(t) -- gt f~ ' where into
t -9 gt
L°°(~) ( = space of
t~ s ~.
Then
is a continuous
N-essentially bounded
u-measurable functions]. The proof of this theorem depends on the following observation.
The part metric
d
In each part
topologically equivalent to the functions from
vN
(containing
~) is
L~°(u)-metric on the corresponding
P~ = ~ g " g ¢ L°°(s),
g
is positive and bounded a~Tay
0 }.
For a proof see
pp
27 in
[2].
Michael's theorem in section l.
Compare this theorem with Here " t h e Banach space
Y''
is replaced by a convex set with a complete metric which is convex in the sense described above. (d)
Fixed point theorem and the selection problem :
has proved the following result. subset of the Euclidean
Let
n-space and let
continuous set valued function from for every
x ~ M, the image set
convex.
Then
a point
x°
T with
M
M
Kakutani
be a compact convex T
be an upper semi-
into itself such that
T(x) is nonempty, closed and
admits a fixed point, that is, there exists xo ~ T(Xo).
We will presently show how this
theorem can be viewed as a selection problem.
For this we need
some preli~iniaries. Let vertices
S = [al, a2, ... an+l ]
stand for an
a l, a2 . . . . ,an÷ I. Given a simplex
the point this simplex. O, I, 2, ...
[a I + a2 + ... + aj]
n-simplex
with
[al, a2, ..., aj],
Ls called the barycentre of
The barycentres of all the faces of orders of a simplex
S
determine a family
S (I)
of
n
90 simplexes,
called the barycentric
the properties (i)
n
simplex of
a face of dimension if an
O,
n
S (I)
and
~ Jl' J2 .... 'Jk} ~
S, with
contains the barycentre of
S (I) contains the barycentres
Jail , ai2, ..., ~ p ] ,
where
k < p,
~ il, i2, "'., ip } .
If we divide each n-slmplex of
S (I)
obtain a new family of n-slmplexes,
in a similar manner, we called the barycentric
division of order 2, which we denote by process,
of
of a face of dimension i, etc.
simplex of
of [aJl , aj2 , ... ajk] then
I
"
each
(ii)
division of order
S (2).
Continuing thls
we can define the barycentric division
S (k)
of order
k. Let
T "
S -> S
be an upper semicontint~us
f~inctlon such that for each subset of
S
where
S
of the kth barycentric bk
be a point of
x e S,
T(x) is a nonempty closed
is an n-simplex. division
S (k)
T(a k) and write
x ¢ S, we consider a n-slmplex
set valued
For each vertex
of the simplex
b k = ~k(ak).
S~
ak let
For each
[ k I[ k ] ~ s(k) ai I, ai~, ..., a~n+ 1
which contains it and we put
~k(X) = ¢k(Pl aikI + P2 ~ 2
The function of
S (k)
Sk
+ ... ) =
k k PlSk(ai )+P2@k(al )+ .... i 2
so defined is linear in the interior of a simplex
and is therefore continuous ~
moreover it is uniquely
determined,
even at the points which belong to several n-simplexes
of
consequently
S (k) ,•
Ok
is continuous in
S.
Hence by
9i
Brouwer's fixed point theorem (which asserts that every singlevalued continuous function from there exists a point S
xk ~
S
is compact, the sequence
k
k
~ +i ]
La I , a2, ... the point
Xk,
S
such that ~Xk}
is an
where
xk = Ok(Xk).
has a cluster point
s(k)
n-slmplex of
Since Xo.
If
which contains
we can write
...)=
Xk : $k(Xk ) = Ck (pk ak + pk a k +
k k k k Pl bl + P9 b2
=
into itself has a fixed point),
bk ~ T(a~)
and
+
"'"
+
bk ~ T ( ~ ) ,
p]k Sk(a~) + pk ~ k ( ~ ) +
k Pn+l
...
k bn+l
etc.
Without any loss of generality we shall assume that, XXk k --~ --~ Xo, Xo, a~
Since
b
k
o
k
-~ bi' k_~ bi
-> Xo,
continuous, we have
o
Pi -~ Pi o bi,
as
k -->co
k k b i ¢ T ai
o
b i ~ T xo
for
for
and
T
i -- 1,2,... n+l. is upper seEi-
i = 1,2, ... n+l.
Now we have the following proposition. Proposition 9. I "
Let
S
be an
functions defined as above and continuous with given a
¢ • 0
n-simplex.
T "
S -> S
Let
N
be
be upper semi-
T(x) nonempty and closed for each there exists an integer
Sk
x e S.
Then
such that for all
k~N, d($k(X),
Remark
9.3
"
W(x))
• ~ .
If the slngle-valued functions
Ck
(as defined
above) converges uniformly to a sing!e-valued function
¢o
then
92 ~o
is a selection for
T.
This can be seen as follows.
the definition of the functions of the functions
Sk
to
Sk
and the uniform convergence
'9o, we have,
d($o(x)0 T(x)) 2 d($o(X) , Ok(X)) + d(~(x), for
From
T(x)) ~ ~ + ~ = ~
n ~ i~(¢). Now we are ready to state the following theorem
(which is a slight extention of Kakutani's fixed point theorem) due to Patnaik " with
[9]. Let
T
be an upper semicontinuous map from
T(x) nonempty and closed.
Let
Then there exists a fixed point under
Sk
converge uniformly.
T.
The truth of this theorem can be seen as follows. Sk(Xk) = xk
and
xk -~ xo
uniformly and since that
xo ~ T(Xo).
$o
as
S -~ S
k --~co.
Since
is a selection for
T,
We have @k "~ $o it follows
In Kakutani's theorem we assume each
T(x)
is nonempty convex and closed but here
T(x) need not be convex
for each
~
x.
Of course here we assume
converges uniformly
to ensure the existence of a fixed point. (e)
Control problems of contingent equation •
~ow we shall
consider the control problem and sketch a proof due to Kikuchl for the existence of optimal control [4].
We shall make the
following assumptions. (I) defined in (2)
F(t, x, u) I xR m XR r
is a compact set (in where
I = ~to, to + a] C
F(t, x, u) is measurable in
~t ". t ~ T, F(t,x,u) c
C }
R m) valued function
t
R'.
[that is,
is measurable for every compact set
93 C
in
Rm]
for each fixed
in (x, u) for each fixed (S)
(x, u) a R m
(4)
Q(t, x)
defined in
t s I.
I x Rm
is a compact set
(in
and measurable in x
Rm ~
Rr
Q(t,x)
t
R r) valued function for each fixed
[that is, for every
we can find some nelghbourhood
N~ (Q(t, Xo))
I x
Rm.
and upper semlcontlnuous in
ts
and continuous
F(t, x, u) carries every bounded set in
into a bounded set in
E ~ 0
×
for every
V
x s V]
of
xo
xo
x ~ Rm, and
such that,
for each fixed
I. (8)
Q(t, x) carries every bounded set in
bounded set in
(6)
Rm
into a
R r.
R(t,x) = F(t,x,Q(t,x)) = ~ y • y ~ F(t,x,u),u z Q(t,x)}
is a compact and convex set (in (7)
I ~
For every
holds for every
y
t
and
such that
x
Rm) for each (t,x) s I x and
R m.
u ~ Q(t,x), x.y _< C(Ixl2+l)
y ¢ F(t,x,u), where the dot denotes
the scalar product. (8) (in in
K
is a compact set in
Rm.
Rm) valued function defined in
I
K(t) is a compact-set and upper semlcontinuous
t. (9)
f(t,x) is a real-valued defined in
measurable in
t
for each fixed If
x ~
R m, and is
R m, and continuous in
x
t e I, and is bounded from below.
u(t)
measurable in
for each fixed
I ~
is a measurable function in t
for each fixed
R r,
F(t,x,u(t)) is
x z R m, and is continuous in x
94 for each fixed
t ~ I.
Therefore
for each measurable function
u(t) the system of equations,
x(t) ¢ F(t, x(t), u(t))
for almost all
t ~ I
x(t o) -- x °
has an absolutely continuous solution if
x(t) for every
x° ~ Rm,
F(t, x, u) satisfies the assumptions stated above. We say that
control
x(t) is the trajectory corresponding to a
u(t) (measurable in
x(t) is an
m-dimensional,
t
and
~
Q(t, x(t)) on
I) if
absolutely continuous function
satisfying the above system of equations. We say that a control ~ I, transfers corresponding to
K
to
u(t)
u(t), defined for
K(t)
to _< t_< q ,
if one of the trajectories
satisfies the relations
x(t o) ¢ K
x(t) and
x( ~ ) s K ( ~ ) . We shall consider the problem of finding a control function u(t) which transfers
K
to
K(t) and wFzLch minimises the cost
func rio nal
J(x)
:
S
f(t, x(t)) dt
to where
x(t)
is one of the solutions corresponding to
represents a value of Theorem 9 . 4 • satisfied.
t
such that
u(t), and
x(t) s K(t).
Suppose that the conditions stated above are
Also suppose that there e ~ s t s
u(t) which transfers
K
t~ K(t) on
I.
at least one control
Then there exists an
95 optimal control, that is, a measurable function one of the corresponding solutions, x*(t o) s K,
attains
u*(t)
for which
x*(t), with initial condition
K(t ~) for some
t* e I, and
t*
inf JCx) = J(x*) = S fCt, x~(t)) dr, t0 where, in addition,
u*(t) ¢ Q(t, x*(t)).
We will indicate the proof of this theorem. all the
Consider the set of
x(t) satisfying
~(t) s F(t, x(t), u(t)) almost everywhere on x(t O) ~ K
and
x( ~ ) s K( ~ )
for some
addition,
u(t) s Q(t, x(t)) for some control
such solution exists by hypothesis,
~ ~ I, where, in u(t).
Since one
this set is r~t empty.
Consequently we can select a sequence of trajectories on
I,
I,
~x n (t)}
with tn
J(x n) =
I t
f(t, Xn(t)) dt
0
decreasing monotonically to value of
t
such that
Inf J(x),
Xn(t) ~ K(t).
~Jhere
tn
represents a
N~q(t) satisfy the following
relations ~n(t) ~ R(t, Xn(t)) almost everywhere on
I
and
Xn(t o) ~ K.
solutions of the contingent equation
By the compactness of
[See pp 98-96
in [4]
a proof of the compactness of solutions] we conclude that
for
96 ~*(t) s R(t, x*(t)), where
x~(t)
x~Cto) ~ K,
is a limit function of a subsequence of
~Xn(t) } .
Also we can select a further subsequence (~ithout changing the notation) such that
~tn}
is a compact interval. of
~Xn(t) }
that
converges to some
K
and
measurable function
since
I
Further, making use of the equi-continuity
and the upper semi-continuity of
x~(t o) s
t* ~ I
x*(t*) ~ K(t*).
K(t), we conclude
~ow one can select a
u*(t) such that
x*(t) ~ F(t, x*(t), u*(t))
almost everywhere on
i
and
u*(t) e Q(t, x*(t)) on
I.
Finally
tn J(xn)
=
I to
f(t, xn(t)) dt
approaches
t*
I
f(t, x*(t)) dt
to as
n -~ oo and hence
tO _< t _< t*
inf J(x) : J(x*).
Thus
x*(t)
on
is optimal.
One could state theorem 9.4 more generally in view of the results in section three but we will not be doing that now. results in this connexion refer [5] where the set
For further R(t, x) is not
necessarily convex. (f)
Set-valued measures "
We shall now discuss about set-valued
measures which have many interesting applications in Mathematical economics.
See Debreu and Schmeldler [5]
and
Vind [i0].
97 Let
(T, T)
be a measurable space, and
dimensional real vector space. (T, T)
is a function from
S
be a finite
A set-valued measure
T
@
to the ton-empty subsets of co
which is countably additive, that is,
_T.
S,
CO
U Ej) = 2 $(Ej) J=l J=l El,oc~, ..., of mutually disjoint elements
for every sequence of
on
Here the sum
Y Aj J=l
@ (
of the subsets
~,
~,
..., of
cO
S, consists of all the vectors
Z where the series is j=l aj, aj ~ Aj for every j = 1,2, . . . .
absolutely convergent, and ~
.
~
"
Let
valued measure ~(E) ~ ~(E)
~
~
a =
be a set-valued measure on (T, =T).
on (T, T)
for every
is a selector of
@
A vector-
if
E ¢ __T.
We investigate now the existence of selectors, and their oroperties.
In particular, the following problem is interesting •
Give conditions implying that for everj
E ~ T
x ~ @(E) there exists a selector
~
Recall that measure
k
@ if
t~ of
~ud every
such that
~(E) = x.
is absolutely continuous ~ith respect to the k(E) = O
implies
@(E) = ~ 0 }.
i~ext we state
a theorem due to Artstein LI]. Theorem 9.~ :
Let (T, T, k)
and non-negative.
Let
~
k.
Then for every
@
k
is finite
be a set-~alued measure, with convex
values (that is, for each S), and such that
be a measure space,
E ~ T, @(E)
is a convex subset of
is absolutely continuous with respect to x ~ @(E)
there is a selector
~
of
~
such
that ~ ( E ) -- x~ We will indicate the main steps in the proof. proof refer to Artstein's paper.
For a detailed
98 Note that it is enough to consider the case a singleton then and
$(E) -- ~ ~(E)}
%z is a measure.
Thus
~
x ¢ $(T).
certain
If
$(I'), ~ d
-- sup
p.y:
inf
Now define for every
Sp(E) # @
and
suppose dim ~(T) • O. ~(T)
then for a
~
of
x ¢
Indeed, since E.
Obviously,
Sp
Then one can show that x ~ Sp(T) it follows ~p(T) has dimension
such that
tz(r) = x.
It is clear that
~.
relative interior, one can construct a suitable
set valued function
G
such that
I G(t) dX(t) = relative interior of $(E) for every E
I G(t) dX(t)
g
t]. of
X
and
f(t) z G(t)
for
X-almost
In particular, there exists an integrable G
~(E) = I g(t) dk(t). E
E s T. =
stands for the set of all integrable functions
with respect to the measure
all values of
and
According to the induction hypothesis there is
is also a selector of When
$(T) }
p.x = U p ( E ) } .
for every
$(T).
a selector
selection
Proceed
}
p.y " y
is a set valued measure.
less than
f
E ~ T ,
E z 2, ~ p ( E ) = sup ~ p.x " x ~ O(E)}
@p(E) = ~ x " x ~ $(E)
[Here
is
p ¢ S,
•
that
$(T)
is the required selector.
x ~ relative interior of
p.x
Sp
If
is a singleton for every
by induction on the dimension of Let
E = T.
such that Then
~
I g(t) dX(t) = x. T
Define
is the required selector.
99 One can give examples to show that theorem 9.5
is false
without the convexity assumption or without the condition that @
is absolutely continuous with respect to the measure
k.
We will close this section after ~entioning the results obtained by and
Y
L. D. Brown (Personal communication).
be a non-metrizable compact space.
a-fields of subsets of
X
and
Y
Let
Let
=X and
respectively.
X = Lo, I] =Y be
Of course
is the usual Borel G-fleld containing all closed sets of Let
C
stand for the product G-field generated by means of
rectangles
A xB,
Baire a-field on
A ~ ~, B ~ Y. Y
Let
then projection of
analytic but the result is false if Y.
If
X.
Y
is the Baire ~-field on
Y Y
S ~ C. S
If
onto
__Y is the [O,I] is
is the Borel
G-field on
and if the continuum
hypothesis is assumed to be valid then there exists a measurable selection of -~ Y.
$, that is, a measurable ft!nction
L I also understand from
f " Projection LS]
L.D.~rown's Co,~munication that
he is writing a lecture motes on Statistical decision theory ,~hich will contain a chapter on applications of selections theorems to decision problems with new proofs of so~e of the selection theoreEs].
100
REFERENCES
Ill
Z. Artstein,
Set-valued measures, Research Memorandum
No. 66, [1971], Department of ~thenatics,
Hebrew
University, Jerusalem, ISRA~Iu.
[2]
H. Bauer and .H.S.Bear, The part metric in convex
sets,
Pac. Jour. l~ath. 30 [19A~9j, 15-83.
[3]
G. Debreu and
D. Schmeidler,
lhe Radon-Nikody~ derivative
of a correspondence, to appear. [4]
N. Kikuchi, Control problems of contingent equation, Pub!.
[5]
RIMS
Kyoto Univ.
Set. ~I 3 [1967], 85-99.
N. Kikuchi, On contingent eouations, Japan- U.S. seminar on ordinary differential and functional equations, [1971], preprlnt.
[6]
L. F. McAuley and D. F. Addis,
Sections and Selections,
to appear.
[?]
E. Nichael, Continuous selections If,
Ann. Math
64
[1956], 562-580. [8]
E. Michael, Continuous selections iii, 2ran. M~th 64
[1957], [9]
375-~90.
S. N. Patnalk, On the K~kutani fixed point theorem and its relationship with the selection problem I Springer Verlag Lecture notes in Nathe~atics, edited by W.M.Fleischman, on 'Set-valued mappings, selections and topological properties of 70-73.
2X ' , No .171, [1970] ,
101
[10]
K. Vind, Edge~orth-allocations in an exchange economy with many traders,
Int. Econ. Rev
8 [1964], 168-177.
