MATr|EMATICAL SYSTE INECONOMICSt1 S .N . A F R I A T ft \ ir..JA,ate++oo 'G. BAMBERG Augsburg Editedby til. elcnnonru Herausgegeben von Karlsruhe ,,
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G.HAMMER Augsburg R.HENN Karlsruhe R. KAERKES Aachen
K. NEUMANN Karlsruhe H. NOLTEMEIER Grittingen
o. oPrTz lnnsbruck
B. RAUHUT Aachen J. ROSENMULLER Karlsruhe R . W .S H E P H A R D Berkeley
Production Duality and the ' . vonNeumann Theory 0f Growth andfnterest S.N.Afriat
VERLAG A1{T(IIT HAII{' MEISENHHM Ail GLAI{
MATHEMATICAL SYSTE r1{EC0N0M|CS11 Editod by Herausgegeben von
S .N . A F R I A T Weterloo G.8AM8ERG Augsburg W.EICHHORN Karlsruhe
G.HAMMER Augsburg R .H E N N Karlsruhe R,KAERKES Aachen
K. NEUMANN Karlsruhe H. NOLTEMEIER Gdttingen O. OPITZ Innsbruck
B. RAUHUT Aachen J. RGENMOLLER Karlsruhe R.W. SHEPHARD Berkeley
Production Duality andthe vonNeumann Theory of Growth andfnteres S.N.Afriat FacultV of Mathematics Universityof Waterloo W a t e r l o o ,O n t a r i o , C a n a d a
VERLAG ANT(|T{ HAII{. MEISEI{HEIM AiI GLAI{
- Meisenheim am Glan @ 1974 Verlag Anton Hain KG Meisenheim am Glan Herstellung: Veilag rtnton Hain KG Printed in GermanY ISBN 3445{l I l3-3
PREFACE Von 1gs'nqnnre econoolc nodel, 1938, has had a steady attentron, ln
trangratl0n
part
ln 1g45.
of rrhlch ls
the orlglnal lntereat
hae frequentry
the origlnal partlcular
nodel. forn
(f956).
eepeclarly
can be traced
relatlon
a rDore abetract
flrst
eepeclally synnetrlcal
of such productlon
ln regard to featurea connectlon
deflned
wlll
economlc 6ense ' ls
relatl'one,
that
slnce the productlon
reratlon
thle
dual
result
plane rhere
no ahort
cute for
maxlmum growths
aeverar
greater
wllr
be treated
relatlon
of producte
nathenatlcal
growth
acroaa each elngle
froo
18 the product
an
of productlon the theoren
of the duale. ln the von perlod,
An apprlcetlon
of
theorentt,
ln
together
than 18 poaalble perlod.
slth
acroaa a elngle
are taten
a
of identical
senee froo
type of t'turnplke
perloda
for
which derlve
power of the dual.
leadg to a nodlfled
long-run
by Davld Gale
acroas any extended perrod
le the correepondlnt
of
be ln the
A baaic operatlon,
Neunann econouy la a poner of the relatloo lte
The
theory.
a further
the fornatlon
the dual of a product
whlch
paper.
glve a posltlon
of duality,
and 1t galne a further
(Sec. 1l)
will
relatlone
wlth
for
or elaboratrone
consideratlon
type but ln the dual apace of prr-cea. lnnedlate
here,
whlch appears in the noder,
von Neurnannfs growth and lntereet
The theory
llteraEure,
back to that
Ilere the lntereat
paper of
eince the repubrlcatlon
gone towards varlatlons
The study of euch relatlons
revlewlng
in hls
in the blbltography
of production
glven
and wae flrst
nlth
There r.e now a subetantlal
represented
stluulatlon
dealt
there
that are
by coapouodlng
ThereareotherthcoreogaboutthepreeervatlonofProPertles
theorem shoss a duallty
tyPe of
Another
of the duel.
property
a correspondlng
I'lth
of a relatlon
! proPerty
connectlnS
propertiear
between
or duallty
or equival'cocee of propertles'
ln producta,
betweencostanrdreturnfunctlona'wlthanexchangeofrolebetleen
of
vork
related
Thla type had lta
and 1ts dual'
a relatlon
(1967)
Rockafellar
froo
suggestlon
orlglnal
the notatlon
, and aleo
heueedwhlchexpreaaesananalogywlthcooJugacylnalinearspace ueed here (Sec' 10)'
has euggeeted that
(12-18)
sectlons
Later
results
and certaln
topology
theory,
extenaLona
baeed on hla
and flnite
frorn three
algebra'
arguoent'
Hle @rn topologlcal
II'W' Kuhn tellg
ln
full
me ln thie
lnportance
out to von Neunann the
from convexlty
derlve
theoreu, le preeented
lnteraectlon
necessary nodlflcatlon. he pointed
the nethode
Hle
feeture'
ln the duallty
then are revlesed
of
ln vhlch
posl'tl-ons,
alternative
brlnge
fashlon
and ln a typlcal
of a productlon
on the baels
theory which von Neunann'elaborated relatlon
the growth and lntereet
deal wlth
wlth
a certaln
connectton
that
of the regularl'ty
conditlonsvhlchappearlnthelatertheoryofDavldGale(1956)but are mleeing ln hle diecueelon lt
(c.f.
bears in von Neunannta actual
there
ls
another Polnt
Together which
1g a rate
wlth
Kuhn (1971)).
The oatter
argument le elaborated
here'
a8 but
beeldea'
the oaxlnr'u
at whlch
at leagt
grortth
rate
of the von Neumann theoryt
aone goode can Srorr'
lt
18 natural
any poealbly
to conelder can gror thle
particular
naxlnum,
of grovth
conslderatlon group of goode.
goode almrltaneouely and aleo
rate
at nhlch
ratGa laaocatGd
The upper llnlt
ig here coneldered the reclprocala
(Sectlon
the four 13).
of all
four
of the correapondlng
support
fron
revlsed
at the Unlversity
the Netlonal
ln the Sunner, 1973.
Unlverslty
at thls
flrst
at Chapel Hlllr
of Canada.
Ednin Burmelster
It
I wlsh to acknowledge wtth eemLnar, especlally
of Karleruhe, contJ-nulng earlLer
to Llonel
the von Neunann nunbere
for
of lntereet. palrs
ln a project
part
wlth
support
of Karleruhe
held
thanke the beneflt W. Eichhorn
dlscusslons
at Berkeley.
W. McKenzle of the Universlty of the Unl-verslty
partlal
was preeented at the
of the manuscript,
of Callfornia
wlth
(CS 21.95), and then
Theory at the Unlveratty
Shephard of the Unlveralty
all
prepared ln 1968 at
of Waterloo tn 1973, wlth
when he read and crltl-clzed
lndebted
for
of the von Neumann model
Sclence Foundation
Reeearch Councll
Synposlun on Productlon
of dlecueslona
the rate
factore
(Sec. 16).
of North Carollna
of the Natlonal
for
property
of a nanuscrlpt
Thls work le part the Unlverelty
wlth
any
numbere thue obtaLned are equal ln certain
Then a dletlnctlve
le the equallty
slth
of grosth
together
the dual systen which have ltrterpretatlon Generally
goods ln the economy
all
l{. }lcKenzle (1967) nakee an approach to
Llonel
together.
ln hle
lesser
of the
at Waterl-oo
and nlth
R. W.
I an slnllarly
of Rocheeter,
of Pennsylvanla.
and
ApaperofR.T.Rockafellarhasacloseconnectlonwlththe nork here:
Monotone Processes of Convex And Concave TyperMernolre
of the Amerlcan Mathernatlcal soclety No. 77, L967. T(x)
stands for
the set Rx here.
to the dual hbre. duallty
relatlons
Hls deftnltlon
Evldently
In hls notatlon
hle polar
le to dlrectly
whlch appear here ln sectlon
correeponds
make true
10 as theorema.
the
TASLEOF COMEN.TS
Introductlon 1.
Productlon relatlone
2.
Cleeelcel properttes
3.
Input aod output llnlte
4,
DoDlnatlon
5.
Claaelcel clorure
6,
Propcrtlce
7,
Dual quantlty
8.
Syoctrlcal
9.
Support functlooe
of conpormda and prlcc
rclatlona
duellty
10.
Co.t rnd rGveouc duellty
11.
Cotpound durllty
L2,
Grorth od
13.
Roclproclty
14.
von Ncuoeon rcdcl
15.
Topologlcal uthod
16.
Algcbralcel uthod
L7,
Gap-cycloe aod coqouod fectore
18.
Coopouadgrorth arrd lntcrcrt
ElblLogrephy
lotcrcet
factora
thtoror
Introductlon The econouLc groltth the theory
for
lnltlatlon
deflned
le there
relq,tlon
goode ln any productlon
slnllar
can aa well
functlon,
Sone developments
defined
relation
duallty features.
where these are dlfferent of productlon
concept
of productlon
Ln theory
context
of
analyalet 1g
and lts
lnvolved
dual,
dual of a product of dual Bymetrles
betrreen the
and proPertLee
of one are
There le a parallel
1s the product for
of the duals. lnstance
wlth
relatlons,
has expreaelon
set of the dual;
or the growth
the
There are a varlety
the coet functlon
Lnput 8et of a correspondence
the
sre sddltlonal
honogeneous productlon
claeslcal
besldee,
le a dual
asgoclatlon
of closed convex cone8, but there
Thue wlth
w111
For the claeelcal
apace.
18 a symetrlcal
wttlch
relatlonl
the von Neumann nodel,
Eepeclally
ln those of the other.
on an output
Eut relatloas
a8 the case where there
then arleea
ln the dual prlce
relatlon
theory
of
are
and number of goode.
The flret
there.
homogeneoue caae, there productlon
and outPut
Thua the lnput
and propertles
thus from the lnlttal
agaln have appllcatlon
reflected
and output8
lnpute
good.
Just one outPut
proceed
betneen poselble
be consldered.
the production
Ttre
relation.
perlod.
constructlon
an
of a type of productlon
ln terme of the aame klnd
deecrlbed wlth
of von Neuusnn (1959) glvee
nodel
as a return factor
for
on 8n functlon
a dual palr
glvlng
thls
are reclprocela,
of reletlon8
expreealon
for
the theoreu
of von Neunannwhere the reclprocsl grosth factor for the dual
of growth factore
Beslde the upper llnlt quantlty hle
factor.
becones the interegt
relatlon
vectora
nodel,
von Neurnrnnte theorem ghol'e ig attalned
, Vhich
and thue a naxlnum,
and equal
for
factor
correaponding for
al-nllarly
ln resPect
upper llnlt
prlcee
positlve
rrtth
to PosLtlve
here at the eane tloe
as von Neulannte
are not valld.
A theoreD of
For the more ldentifl-
by Gale 0956 ) theee reclprocal
treared
catlons
theoren.
Eouever,
another
theoren
and
le proved agaln
th18 conslderetlon
lnvolves
relatLong
the
quantltlesr
the dual relatlon.
McKenzle CI967 ) whlch
general
growth
the naxluuo
can also be coneldered
there
the dual relatlon,
of
Ln
lntereat
to the nlnlurm
whlch here appears as the reclprocal
factor,
eemlpoeltlve
for
be proved
nlll
under the weaker ae8ltrPtion8. The von Neuoenn conditlon cycllcal
caae of nore extended sene conclualona repreaenta
together
lt
le that
lt
ls
rrlth
a further
and thue do at leaet
bctter
lqo8elble
by tsklng to do better.
whlch
concluelon
theorem.
18 10 any caae poaelble
acroaa each perlod
power, and poealbly
type of condltlon,
type of "turnpikett
a nodlfled
acroaa N perlods rate
but
a * b > 0 w111 be exhlblted
aa a
glvca
the
ehlch
In grorth
to Srort at the naxinn as rcll
I ttahortrcut".
ea the Nth The concluelon
3
Given any two relatlone flrst
are the eaoe as the lnput
product frdn
A, B where the output goods of the aecond,
AB where z la AB-produclble
eone y whlch
N perlods
ln
goods of
le A-produclble
from x if fron
the von Neuoann nodel
x.
lt
the
they have a
ls B-produclble
Thua the relatlon
ie derlved
acroaa
a8 the Nth powe,
N
R" of the glven flxed Varloue propertles
relatlon
of a productlon
whlch are preeerved for The relatlon palr
R ln
products,
relatlon
(arb)
producti.on perlod.
whlch wllr
tn partlcular
for
be coneldered
powers.
le derlved
from a
thue,
: < R y = ( v g ) x > a t , b t > Y ,
18, R - AB nhere xAt = x > at,
The t here le interpreted from the lnput
x
produces
of the matrices.
the row-orders
tBy = bt I y .
as an actlvlty
and nhich
co@on columr-order nodel
any alngle
the von Neunann nodel
hatricea
of non-negatlve
(1)
that
R for
of the matricea
vector,
the output llhlle
the fornula
that
R ls
dlfferent,
y.
Ite
order
ln the context
are the eame and equal
nunber n of goods ln the economy, the foroula when theee are generally
which ts produced
(l)
aay n and n.
etlu It
le
the
of the to the
makee sense followe
from
1
cloecd:
(1f)
conlcal:
(111)
sddltlve! (rl)
(1),
51nce wlth
*Y
t,
",
xRY 'o xlRYl
(l
+
xRY
3 0)
(x*r')
xRy' xtRyt +
1e equlvalent
R(yly'). theEe ProPertle6
to convellty,
convex cone in 0E t
R le a cloeed
aaaert
*
t,
trRyr,
(1)
On.
hae the further
lt
Alao
propertlee (1v)
dlaPoeal
free of
xRY:
of outPut:
propertlee
The claaelcal be cloeed property
convex and wlth (11)
glvee
free
xtRY
Yt +
for
a productlon
relatlon
lt
that
Thus R t 0n
returns.
by (1) le claeetccl
ale
the honogenelty
Ihen
dlepoeal.
S . 0n x Onodetermlned
ta the relatton
xRYt'
the caae of conetant
(a,b)
fron
deternlned
: : xRY
xt
lnPut:
"
nm
hornogeneoue; and eo aleo
by
PSq = Pa > qb.
(2)
glven by (1) and (2) are dletlngulahed
The conatructlons polytope
and polYhedral.
For any R.
nn t
whatever,
the dual
S * R*, where S c 0rrx
0r,
pSq = xRy =+ px I 9Y.
(3) In ldentlcal
ldentlcal
0D
by
le deflned
The dual
as
fashlon,
of any relatlon wlth
any s has a dual
but lrLth exchange of rolee, is
homogeneoue.
claeelcal
the dual of lte
dual
if
and only
lf
s*.
Alao any relatLon lt
le ltself
l"s
claselcal
homogeneous. For example, R and S glven by (1) and (2) are such thet t
t
R = S for
*
and S = R", as can be verifled
llnear
palr
a, b by (1),
the polytope
wlth
( 4 )
theory
R glven from a
relatlon
the condltion
a * b > 0
Then Gale (1956 ) introduced homogeneous relatlon
whlch together
of a general
conslderatlon
R wlth
condltlons
o(R):
O R Y= + y = 6
can deflne
these conditions
regularlty
R.
for
applled by (2). relatlons
correspond to conditlons
Evidently
then, elther
> 0
one of these condltions
to R glven by (1) 1s equlvalent
to the other
a general theorem, that
Thls lllustrates
applled
for
to S glven
any dual palr
of
R,S o(R) <:+
(5) and slnllarly
with
any dual palr
of releElons,
The property
I (s)
R,S lnterchanged.
of regularlty
lf
and only
(a,b)
at : btU, of a saddle polnt f(p,t)
=
for
lf
the other
ls.
ls
ls preserved also ln products. subJect to
(4) and concluded the
of p > 0, t > 0 and u > 0 such that
equlvalently,
that
A consequence of thie
one is regular
von Neumann consldered existence
to R glven by
Ae applled
(q) t > 0 -+ at > 0 (B) P > O:Pb respectlvely.
claeelcal
x R y , y > 0 f o r s o m ex , y
B(R):
(1),
uslng duallty
lnequalities.
von Neuman considered matrix
dlrectly
pat/pbt
pa > pbb, of the frmction (p > 0, t ) 0),
6
(4) er8ureE
rtrlch
I'ttth
and flnlte.
to u posltlve
(B) corrcapood
(c) 8nd
condltlone
The regularlty
la nell-deflned.
F''nartP:rR:rP, xzo]
le that
the.conclualon
p-', o- are both deflned,
and
and flnlte,
Posltlve
of
equivaleot
to S' another
ln reaPect
correepondlngly
and E deternl.ned
Introduclnt
Io-1.
i - auPtP: xR:rP,x > ol, 1a the eddltlonal
there
McKenzle (1967),
cen generally
that
o-- l
rtreni
lenot
Productloo A etock
vactora. 0 belng
y)
coluul
vectora
p ln the dual
Tten the exchange value the non-negatlve
dual,
all
f.
But
d i-
1, i 6-
by a vector
x ln the
of order
n.
Ttre prlcee
epace O' of non-negatLve
of quantltlee
x at prlcee
1
are rot
p la px e 0'
ilrders.
actlvlty
cooverta
a atock
of aone n goode y e nn, eo lt
of solc
of productlon
are deecrlbed
m goods x e nn
le descrlbed
e nn t 0m, x beLng the Lnput and y the output.
poeelbtlittee
lta
o fe 6 d:
the reclProcal relatlott.
of sone n goode le repreeented
A productlon
(x,
and S lc
of [,
hmogeneoue
claeelcal
rclatlone
by 6 vector
i.nto a etock
regular
be eald of the relatt'on
apace nn of non-negatlve represented
"otteepondlngly
dnetead.
are eetabllahed,
1.
deteroined
i
ae by Gale (1956),
va1ld
way by
la another
obtatned
However, nhen a general
R 1r coneldered,
rrlatloo
i' - i,
wlth
and slnllarly
to S.
lD rcapect
concluelon
by a palr The the
by a productlon
reletion
7
R c 0n r 0D, where the condltlon wlth
lnput
x and output
recorded
for
relatlon
introduced
growth.
If
lnput
there
to the standard
y, or that
and output
a feaslble
y is produclble
fron
ls a slngle
operatlon x.
rf
the goodg
are the seme then n = m. such 1s the type of
by von Neunann in the treatment output
of econonlc
good then m = 1 and R corresponde
concept of a productlon
For any productlon xR c 0n glven
xRy stgnlfles
functlon.
R c Qn x em and x e On, the aet
relation
by x n = [ y : x R y
deflnee the output possibllity
set of R for
any y e 0n the set Ry c fln given
for
an lnput
x.
Slurllarly
by
R y = [ x : x R y ] ls the lnput posslblllty
set of R for
an output y.
Glven two productlon relatlons A.0r lnvolvlng
r * s + t goode partlt,loned
class of s goods belng both output product
x ns, B.
in three
ea * Ot
classes,
for A and input
the nlddle
for
B, a thlrd
AB c Qr t 0E is determlned where
relation
xABz = (vy)xAyBz Thus the condltlon
that
z be AB-producible
a y wtrlch 1s A-producible A productlon x6Rys(s = L,2, ls
relatlon
R . Qm r Qn ls contlnuous y" o y (s + -)
to say R is a closed subset of em t en.
that
all
its
lnput
sets Ry . 0t
(x e nn) are closed.
x ia that
there
existg
from x and from whlch z ts B-produclble.
and x" - *,
...)
fron
lnplies xRy, whlch
Continulty
(y g Xm) snd output
Also R is convex if
lf
for
R inplles
sets xR c em
8
xRy' x|Ryl-+
ie a convex subset of 0n x 0n.
whlch ls to say it
A productlon lnput
and output
input
lts
all
that
luplles
(xl + xltr')R(yr + yll')(l,tr'
Convexity
R
for
sets are convex'
R has the Property
relatlon
- 1),
o,tr + lt
2
of free
for
disposal
lf xr :
and for
output
xRY '+
xtRY ,
Y'+
xRY' ,
l-f xRY ?
and thus for
both lf x R y Z y ' Z
x ' ] Equlvalent
st-atements of lnput
o + x r R y r .
and output
are
free disposal
x t a x + 1 f t c 1 r ! ' , Y aY"+
RY c RY' ,
and agaLn x e R y r x t l x + x t e R Y , y e x R , y : Y t + Y r e x R , provldedy']o.Accor
the translatlon
As a unlon of translatlons called
orthogeneous,
wlth
of the non-ne8atlve
orthant
resPect to the non-negatlve
the second condltion
slrnllarly
orthant.
x + Qn of the non-negatlve
sholrs xR is
Lt can be orthant'
the truncatlon
wlthln
the
non-neSatlveorthantofthesetxR]lwhlchlsorthogeneouswlth respecttothenon-posltlveorthant.HereR>denoteetheProductof R wlth
>
Thus the characterlstic
of a productlon
reLation
whlch
haefreedlsposalforlnputandoutputlsthatltsinputandoutput
9
seta ere orthogeneousr convexr
2.
they
ln the oppo'lte
are called
Claeelcal
orthoconvex
convex and wlth
productlon
free
output
poeelblllty
further
poeslble
dlepoeal
tor
as'uttrptlon for
at leaet
none decreased, by a strr.ct
output
claeelcal
output
they are
respectlvely.
a production
productLon
becones the catagraph, Thus nlth
the correspondlng
a claselcal
productlon f(x)
and A
R le that
> y ,
lnputs.
property
when there
corresponds
which
functlon
or the reglon
lnput
can always be lncreaeed
functlon
aa a coucave eenl-lncreaaLng
relatlon
of all
thls
rta
and orthoconcave.
(vyt)xtRyt
increaee
to be contlnuou',
and lnput.
aome output
R wrth
of a claaelcal
functlon.
ie deflned
aeta are cloaed orthoconvex
and whlch meana that
concept
also
and orthoconcave
relatlon
xr > xRy .+
output,
rf
oropertlee
A clagelcaL
elngre
aenaea.
of
below the graph,
productlon
le a
to the
deternlneg lnpute.
and
uaxlmuo
rn fact
R
of euch a R c 0n x 0
relatlon
functlon
- nex[y
le concsve, and semi-lncreasing,
: xRy] e e (x e nn; that
is
x r > x - f ( x r ) t f ( x ) . A production
relatlon
showe constant
returns
to scale
lf
xRy+,.F 1o whlch case 1t 1s also output'
so lt
1s llnearly
corresponds
honogeneous,
said
to be homogeneous.
to a productlon
functlon,
rf
there
is Just
then that
one
functlon
t0
A product{on
R le addltlve
relatlon
(r
= f(x)I
f(xl)
: 0)
lf
(x * x')R(Y * Y') '
xRY, xtRYr +
Glventhataproductlonreletlonlshomogeneoue,ltlgconvexlfarrd onlylfltleaddltlve.Dlecussionhereglllbenalnlyaboutclaael.cal relatlong'
homogeneoua production
3.
Llmlt
LnPut and output
For any lnPut
(Y t * { t * t Y +
e l n f A =
and then there
le deternlned
where
A le deternlned
set A t 0n, a eet inf
Y t I ( v z )z e L ' x < z S !
the 8et
nlnA-AnlnfA. If lnf
A c A' 80 that
A tg closed then lnf A la called
a lower
' and any Polnt
llmlt
Ihe orthogeneous cloaure
lnf
nln A'
orthogeneoua,
set wtrlch contalns If
A ls closed
contalna
Any polnt
of of A'
of mln A a mlnluuo'
of A is
i - t * : x t : x , x ' e A l Ttrls ls
A'
A and ls
contalned
A, and A le orthogeneoua lf
. ln cvery
and only
lf
orthogeneoue A'
['
then
i - (rrn l)' ThuelfAlsaclassicallnputset'thatlsclosedorthogeneouElnthe lnput
space 0n, then 6 -
Thua a cloeed
orthogeneous
eet A ls
(nln A)< determined
Juet by lta
DlntDs'
ll
Further,
for any set B, 6 = f
Also mln A, whlch
. o m l n A c
is now glven
B c
A
by
x e mln A .<:.
x e A, xr < x:
xr e I
le a subser of the boundary bdy A of A glven by
though 'r,, o
".1 ;"tr:"-".:r.,
^ ," :"""":;r;'":r:"".*.
An orthogeneous set 1s necessarlly compact.
However, by a compact-orthogeneous
closed orthogeneous set A for that
unbounded so lt
with
set wl1l
be meant a
whlch nin A ls bounded.
A closed so ls mln A.
cannot be
rt
can be seen
Thus conpact-orthogeneous
A hae mln
A compact. For any output negatively
set B c en, slnllarly
orthogeneous closure
I
t'
sup B, nax B and the
nt are defined,
with
correeponding
propertles.
4.
Input
and output
rank
Glven a production
relatlon
R c 0n x om, lnputs
ln an order H . On r en where xtHx, or x, every posslble
output
is superlor
frour x ls also an output
can be ranked to x,
from xr,
that
lf 1s
x'Hx = xrRy <: xRy , and thus xtHx.+ Fron here evldently Also
H is reflexlve
xtR:
xR.
and transltive,
so it
is an order.
l2
Itx-n[Ry:xRY] Hence 1f the eete Ry are closed orthoconvex' relatlon
productlon
a claee{cal
ae wlth
lnterRr Ehen ao are the sets Hx' slnce they are
sections of these. K where
are ranked ln an order
outputs
Sirnllarly,
YKY' = RY t RY' , that
ls,
y ls
superlor
to yt
yt can be produced from every x from
!f
Then
whlch y can be Produced.
n[xR:
yKle cloaed orthoconcave
xRY]
ln case of claeelcal
Speclal
R'
structures
forRarereflectedlnepeclalatructuresforltandK.Foraelnple example, lt
appears that
order
H le a conplete
and only
lf
lf
K la a
completeorder.InthatcageRadmitsfactorizatlonlntoaproduct R-ABwhereArtt
r0,
case, between lnPut and output produced from the lnput There exlsts
an output
there
lnterrnediate
la a elngle
ls
and fron whlch the output functlon
xAt <:
the
0 " 0m. For anotherdeecriptlonof
B e
f(x)
f(x)
tBy <:
> t,
then produced'
functlon
and an lnput t :
good'
and
g(y)'
g(y)'
so that
rRY <:
11*;
: 8(Y)
and
x'Hx <+ f(x') > f(x),
5.
Claestcal
e(f) 3 g(y')
closure
Glven any relatlon R = i.
yKy'<:
T c Qn r 0m, lt
This ls a classlcal
production
has a claeaical relatlon
closure
whlch contalns
T and
l3
la contalned
ln every claealcal
An lntereectlon lnteraectlon contaln
T.
of claeelcal
relatlone
productlon
reLation
le cloaed bounded, generator. then ao le lts
cloeure,
relatlon
relatlone
a generator
whlch of T.
Slnce 1f any T le a generator
ie compact lf
lt
this
A that
of R
neans a
hae a bounded generator, Any output
T.
ie the
le one whlch hae a conpact,
a coupact convex generator.
posslbtllty
contalns
and thls
and aleo Lts convex cloaure,
eete xR of euch a relatLon lnput
vhlch
claeelcal
R - T then aleo T can be called
If
alternatlvely
relatlon
ls classLcal,
of the non-eDpty set of all
coppact claealcal
productlon
productloo
or
poeslblllty
te compact, ln the usual eenee, and any
sets Ry ls conpactr
ln the aense that
lt
le cloeed
and min Ry la bounded. A polvhedral generator.
clasalcal
Thua aleo lt
productlon
le conpact.
relatlon It8
lnput
ls one w{th a flnite and output
poeslblllty
sets are convex polyhedra.
6.
Propertlee
of conpounde
Each of the propertlee addltlvlty,
compactneas and flnlte
Honever, a product contlnuoua, a further
of free
of contlnuous
dlspoeal,
generatlon
assumption.
assumptlon appears as follows.
XRla bounded for
bounded output
returns,
ls preeerved
productJ.on relatlons
except under gone further
le gald to have strlctly
conetant
in products.
la not necessarlly
An example of such
A production
reletlon
R
lf
[y : x e X, xRy] = u[xR : x e X]
every bounded input
set X.
Also R can be said to have
l4
Lf.
bounded outDut
However, the converse holde for
does does not hold generally. productlon
whlch has free
relatlon
obvtousl,y
though the converse
bounded output,
inplies
bounded output
strlctly
x.
lnput
every
xR ls bounded for
For l-n th18 case
lnput.
for
dlsposal
a
y:x-yR>xR,andiflisboundedthereexlstsysuchthatxeX=+YR
yR r
ls
It
lnput,
the bounded output
Then
dlepoeal
condltlon
xR ls bounded for
al1 x ; 0
xR ls bounded for
some x > 0 .
to
equlvalent
appear that
wlll
free
R wlth
relation
For a homogeneoua productlon for
x'
yR ls bounded.
xR ie bounded if
Bo that
*,
y:
bounded there exists y such that x e X+
xls
and lf
lf
also R la contLnuous,
then another
equlvalent
1e o R y +
Y = 0 ,
whlch le to say Ry does not contaln conditlon
ls preserved
hol'ds for
Another condition ls preserved
for
products.
for
on a production
thls
it
holds
ls
for
Y = 0, so that
relatlon
A and B oABy impLles
whlch obvlously
the feaslble
output
for
all
condltion
Y 2 0 for
For R whlch is honogeneous and has free
obvlously
laet
Thls
1s
Ry 1s non-enpty
relatlon.
y > 0.
AB.
products
Thls can be called
all
For lf
x = 0, and then lnplies
then oA:
0 for
equlvalent
to
a Production
dlspdsal
for
output'
l5
Ry le non-enpty Thle
condltlon
applled
to a claeslcal
w111 be aeen to have a dual (see Theoren 8.5, wlth
eone y > 0 .
for
houogeneous productlon
relatlonshlp
relatlon
to the bounded output
condltlon
Theoren 6.2).
Theoren 6.1 If output
productlon
relatlons
x"Cz" then for
*x"
[xs:
s],Y-
Y contalns
[y":
a lln1t
correspondlng convergent
xcz,
el,Z-
polnt
for
strlctly
bounded
for thls
"r-
A, Y le bounded.
Hence
Let xr
, zt be
any subeequence.of
to the same llmit,
contlnulty
and let
",
ThenX1sboundedsince
Then, eince
Zs.
C - AB.
and let
y, and a eubaequence y; * y.
Hence, by contlnuity
ae requlred remrked,
e].
Then, by hypotheela
sequence ls convergent,
la already
Let *" * *,
[2":
subsequencee of xs,
8ut also xiAfiBz". that
Ql r 0n be as stated,
B.
aome yg, *"Ay"B"".
le convergent.
with
product.
then so ls thelr Let A c nD r 01,
If
are contlnuous
etlll
xr + x,
a
ztr+
of A and B, xAyBz, whlch shons
of the product.
SLnce the rest
completee the proof.
Theoren 6.2 A neceesary and sufficlent productlon
relatlon
condLtlon
R to have strlctly
for
a contlnuoue
bounded output
is
homoleneous
that
oRy +
- 0 . If ORy where y > 0 then honogenelty so the output
posslblllty
have atrlctly
bounded output.
lnplles
ORyl for
all
l
> 0,
Bet 0R 1s not bounded, and hence R does not
y
z.
of lnPut
dlsPosal
Wlth free
x > 0 + x R ) 0 R ,
shown, and lt
is
necesslty
Ihus the
set is unbounded'
case every outPut possiblllty
so in thls
remalns to conslder
sufficlency'
SupposeRlscontlnuousandhomogeneousbutwlthoutstrictly Then there exlst
bounded output.
where x" ls bounded but ys unbounded'
x"RY" (s = 1,2r...) any q > 0.
Then qY" 1s unbounded, and hence qyt * -
subsequence yj
of y".
The corresponding
-1
-1
b y h o n o g e n e r t (yq, y l ) ' * l R y l ( q y l ) - ' ( " '
pomt ! of the rl(cri)-l, Yl euch that
a e u b s e q u e n c ey ' o f for It
yil(qy')
of R, that
by contlnu1ty
of x" le
Aleo *lRVl,
ao that'
-)'
-1 .
N o wq ( v i ( q v ; )
1,2,...).
auch that qi - 1, 8o that i > 0, and - 1^
xi'
the correspondlng subsequencex'of follows,
some
I ls compact' Hence there exLsts
and the 8et of y such that qy' a llnlt
Teke
(s + o) for
subsequence xl
- O (s + -).
bounded, so ttrat xj(Afi)-l
stlll
Y" such that
sequences *e,
- y (e - -)' xi(wi)-l
strfl
CIR!, which,
Then aLeo, * O'
since ! > 0, completee
the proof.
7.
Dual productlon For an actlvlEy
lnput
and output
are px, qy e relatlon
and prlce wlth
prlces
relatlons
input
x e Qn and outPut y e 0n rrhen the
are p e 0r, and g e 0m, the coet and the return
Q so the proflt
ls
qy = px e t fl.
R . on t f,]mhas associated
Rtt c Qn x Qr, nhlch
holds
with
between input
lt
Any productlon
a dual prlce
and output
prlcee
relatlon at which
1'
l1
posltlve
profit
ls
lnposelble
(1) In correapondlng dual productlon
productlon
with
pR*q = xRy o
px
any prlce
realtlon
faehlon,
I
eubJect to R.
Thus
qy S c 0o r 0, deternlnes
S* c 0n r 0m, where
relatlon
xS*y=psq+pxl9y Thue S* deacrlbee non-posltlve Now let
productlon
all
at all
lnput
actlvltlee
and output
T denote any relatlon
prlces
for whlch proflt 1n the relatlon
0n r nn or O
ln elther
D
x fl .
Theoren7.1 T^ . T,'+ U
l
T*: U
Tt
Thle 1e lmedlate
I
fron
the definltlon
Theoren 7.2 TcT** By deflnitton
of T* xTy a pT*q ..+.
px I
9I
equlvalently xTy .+. But by deflnltlon
pT*q.+
px l, 9I
of T** xT**y
.<-.
pT*q +
px ] eI
Thus xTY + ae requLred. Theoren 7.3 T* = T***
xT**Y
,
of the dual.
N
ie S.
lte
l8
By lheorens 7.1 and 7,2, aord2 T*r
(Trt*)* ,
and by Ttreorem7.2 wlth T* 1n place of T' c (f*):t*
l* But
r T*** -
(T**)*
(T*)** .
a
8.
duals
Svroetrlcal
T whlch
A relatlon a dual
called
e\r@etrlcallv
Thua lt
Aleo any T whlch
relatlon.
called
ie of the form T - U* for
dual. that
le l@edlate
Theorem 7.3 ehoare that
It
ls
some U can be
euch that
18 a dual , alnce T'U*
any symetrical
any dual relatlon
T '
can be
where u'T*.
dual ls a dual' ls a reclprocal
T**
Also dua1.
Thue:
Theoren 8.1 A dual
ls
relat'lon
sv@etrlcally
dual'
llencelfTtsadual,lthaeadualU'T*ofwhlchltlsthe dual,
that
lg T - T*.
dual of the other
Such a palr
deflne
a 1!gl--Palr
of relatlons
each of whlch la the
of relatlons'
Theoren 8.2 The relatlone
D . nn " 0n d x D y = x 3 y ,
forn
E . en x 0n gl\renjl P E q = P : q
a dual palr. Thu8, rtLth varlables
taken non-negatlve'
p D * q = x : y - p x l 9 Y ,
t9
. + . x u 0 e P x > g x r . e . D > O
pEq .
.-. Aleo
pEq.-.
p:
q
- x : y = D P x : P y : q y Thus D* - E, and alnllarly Sinllarly
lt
PDttq. E* - D .
can be seen that
for
any u :
0, the relatlons
glven by x G y = x 2 y y , forn
p H q = u p : q
a dual palr.
Theorem 8.3 For any a e 0m, b e en, the relatl.one R. ScQ
-u
xfl
qlvenbv fr
xRy = (vt
> at,
e Qr)x
p S q = p a > q b ,
forn
nn r 0n,
bt
p e Q m ,
:
q € f l n
a dual pair. Thue, wlth
p : 0,
q
> 0 : 0 and r
pR*q=xRy:px:qy . - x i a r , b t z y + p x ] g I <+
pat, > qat
< - p a > q a = p S q . Thue R* = S.
It
reral-na
to shorr' that
S* = R.
y
G, H
20
non-negatlve'
varlablea
all
Thue' wlth
xSiy:paiqb+pxlQY. That 1s, xS*I
and onlY lf
lf
holds
px < QY
pa I qb, has no solutLon
(P, q) I 0.
for
But
(pq)f"l:o (pq)[*l'o |.-bJ (nl)
hae no solutlon
1 0 lf
and only
f *'l
l-'j hae a eolutlon
t I 0, that
The relatlons
Corollary.
[-Y]
f ''l t
-
|.-uJ
1s, lf
and only
1f xRy, ae requ{red'
R, S given by PSq = Pa > q
xRy = x > aY' forn
lf
a dual palr. Wlth reference
to the theoremr let a -
be the natrLces
a, b partltloned
^n ,, b, e Q" (i = f,...,
ao K ls
the relation
(ar, br),
(ar ...
I - 1,.'.'
clasaical
b -
ln thel'r
(bl ... br) columrs a, e nn,
l),
andlet
K -
[(at, br) : I - 1,..., r]
descrlbed r.
by a flnlte
,
set of lnPut-outPuts
Clearly the dual of K ls S'
K c R and K t R, nevertheless, R ls the classical
"r),
K* = R*, so K** - R'
homogeneous closure
homogeneous relation
of K, that
contalnlng
K'
is,
T t r u aw h l l e It
aPpears that
the enalleat
2l
Theoren 8.4 A neceesary and sufflcient 8y@etrlcally
dual ls
The consldered contlnuoua neceeelty deflnltlon
R c R**.
be classlcal
condltlon
of these propertlee of a dual.
Thue, conslder
It
ln
renalne
is
(tv)
that
the arguuent
Rt* - R.
Slnce R le orthogeneoue,
fron
totether
theee propertles
the
they are
relatlon
But for
The
theee propertles.
R wlth
a prlce
lf
be (1)
lt
proved dlrectly
a productl.on relatlon
to shors that
to be
orthogeneoua.
w111 be proved that
hae to be ahorm that
Thus lt
a relatlon
honogeneoug.
on the relatlon
is readlly
Now lt
le no dlfference
lnetead).
lt
for
(11) hornogeneoue (111) addltlve
eufflclent. (There
that
condltlon
ie coneldered
any relatlon, inply
I
c iIT.
by (1v),
I ] 0 . + . x R y < - r * R l y and elnce R le a closed convex cone, by (1),
(11) and (ili),
ao ia
R > . Conalder x:
o, y ] 0 such that x[y. beceuee R > le a closed convex cone, there
rhen friy, erlsts
and hertce,
(p, q) r 0 such
that (a)
x'R I Y' -t
px' 3 9y'
(b) px
y ' , and thls
vtth
(a) lnplies x'Ry' :
(n, S) 3 O. pxt I
qyt ,
Slnce R.
R.,
also
(a) lnplles
22
8nd thls rhat
(p, q) :0
wlth
xi-**y,
pR*q.
shows that
But chis wlth
(b) showe
as required.
theoren 8.5 palr
For a dual
of rel-atlons ORY-
(1)
R, S @19!41tlons
Y=0
and (vp, q)psq' q > 0
(11) are equlvalent. Ir
ls lmedlare
pSq, q > 0.
rhar
(11) tuprles
(1).
For if
(11) holds,
let
Then qSq lnPlles x R y + p x ] 9 Y r
ln partlcular O R Y : 0 : q Y But oTy tnplles
y I 0, and with
thls
and 9 > 0t
o : q y + r = 0 , whlch shows (1). Conversely,
(1) lnPltee R , t ( 0 , Y ) : y : 0 1
are cloeed convex cones where lntersection
ls
0.
Hence there
exlsts
p, q such that (a) xRy+pxl9Y' Now (a) wlth q > 0. (ll),
the monotonlclty
Now (a) wlthp, as requlred.
A]0
(b) Y>0
P:0.
Also
lnplles pSq, and this\tith
(b)
lnplles
q > 0 ioplies
23
A relatlon
T can be called I - o,
oTy Thenthe theorem shows rhat lf
for
if
it
hae the propertles
(vx, y)xTy, y > o
any dual palr
one 1e regular
if
and only
the other ls,
Corollary. if
regular
xR ls bounded for
and only lf
all
* I 0, equl-valent1y for
Sq ls non-enpty for all
q:
O, equlvalently
sone x > 0 for
some
q > 0. The regularlty can be lllustrated derlved
condltlons,
appearlng
1n Theorern 8.5 and Corollary,
by the von Neumann type of production paLr (a, b) and lte
from a matrlx
The condltlon
for
R to be regular
relatlon
R
dual S, ae glven by Theoren 8.3.
are
(1) ORy-y-9 (11) xRy, y > 0 for In terns
of
(1)t
some x, y.
(a, b) they are equlvalently ar - 0 +
br - 0, for all
c E 0n
(11)' bt > 0 for aorle t. Slnce they are equlvalent
to
(c)"
a_, 2 0 for r)
(B)"
br. e 0 for every good l. (r
every activity
r,
Conslder the condltlons ( o )
p > 0 = + p a > 0 ,
( B )
t > 0 : > b r > 0 .
Aleo (o) implles (1)' , and (B)' inplles
(1), while
is equivalent to (11)',
(B) is equlvalenr to (il).
so rhat
(o)
24
| doee not But (1)
nortevcr) (ll)
for
coadltloaa
neccltary
(c),
lnp1y
'
r.)
fron
(1)'
Thue,
eny case wtren Ln
requlree
that
Partlcular
0 -
every r euch that
the .th
if
thern ia unaltered
= 0.
.r)
br)
- 0 for
(a, b),
for
holde
condltlon
of thle
(o) ln
valldatlng
defect'
rrhlch renoves thle
holde,
and (B) as
(c)
of R'
regularlty
le e aenae for
there
ln
Eakes e defect
and thle
r
all
then the relation
froo
le deleted
"o1,-,
R rrhlch derlvee a, b for tt)
a whlch resulte'
In the natrlx
t 0
forallr,eo(cr)''laeatlafled.Itfolloweth8t(1)l.upllee(c)' provlded
(".) tr)) = o for
each actlvlty lnput
wlthout
r,
unaltered
the 1let
of baelc
whenever null actlvlties,
The provlao
is
condltlon
a * b > 0, slnce
lt
and lt
ls
+ br)
ae lrell ln
Theoren 8.6
'' o,.;ni anv For il:;;"."='".T.,, (1)
QRY"+Y'0
(11)
xRY, Y > 0 for
some x'
Y
that
ell
are
the von Neumann
> 0, lnplylng
a . > 0 or b . 2 0, aa requlred. t) t)
the condltlons
actlvltlee.
are added or removed
actlvltlee
glvee .r)
0) whtch le
anong the baslc
ln any caae autouatlc
reuoved.
(0'
actlvlty
lncluded
ia not
or output,
But R renalne fron
le the null
that
that
25
and
( a ) t > o : a t > 0 ( B ) p > 0 - p b > 0 are such that (o) : also
(1) -+
(1),
(B) .o
(o) provided ("r)
Now conalder
the regularlty
(1i) br))
; > 0 for
a1l r.
conditlons
(1)* osq:q=6 ( 1 1 ) * p s q , 9 > 0 f o r s o m ep , q S = R*, where, by theoren g.3,
on the dual relatlon
p S q = p a : q b It
ls obvlous that
equlvarent Obvlously
to also
(1)* ls equlvalent
ro (g),
ao then (1)* 1s
(11), whlch provides an illustration (11;'t Le equlvalent pa > qb for
and hence, by a general
of theoren g.5.
to,
some (pg) r 0,
theoren an lnequalltles,
to the denlal
that
(at,-b)<0forsomet>0, equlvalently,
slnce,
a b > 0, to the denlal
that
a t = 0 , b t > 0 f o r s o n e a 2 0 , equivalently a t = 0 ? b t - 0 f o r a l l t , whlch ls
(1) r.
Thus (11)* is equlvalenr theorem 8.5 again.
ro (1)r,
and hence to (1),
whlch lrru'trates
26
Thefollowlnghasappllcatlonlngrowthandlntereettheory 1ater. Theoren 8.7 Ee,nareclaseicalhomogeneousproductLonreletlonewlth one of A n 8r,
duale u, V then elther
The the converae Bt of B le glven x(A n B')Y t*
by xEty
ln cotmon then there
exlsta
(1)
:rAy -+ px I 9Y
(1i)
YBx
Then input
-o
= yBr'
Ttrus
(p'
they have no Lnterlor
q) tOsuch that
for A wlth
(i)
lnpltee
N o w( i ) a n d ( 1 1 ) w l t h p l 0 ,
and for
p:0,
Thus
Also l n t ( A n B r ) t 0 + U n V r = 0 . (x, y) e int(A
n Br) then,
since (x, y) e lnt
PUq: and slnce
Px > qY
(y, x) e B' qvP+qv:px
Thua pUq :
qlp'
as required.
Thus
i n t ( A n B ' ) = 0 < + U n V ; * 0 , and ldentlcally
wich duals lnterchanged.
B wlth
q:0Ehowthat
i n t ( A n B t ) - 0 ' + U n V t t 0 .
For if
lf
qY I Px
free dlsposal
(11) lnpllesql0. pUq, qVp.
1f and onlv
xAY' YBx.
slnce A, Bt are closed convex cone8, lf point
le null
Lnterlor.
has non-enpty
the other
u n vr
A,
27
9.
Support functlons Glven an lnput
the lower 1ftolt
pos6lb11lty
of input
(1)
aet A c en and lnput
prlcee
cost ls
[p, A] - lnf [px : x e A] = n a x l t : x e A
As a functlon
of p e er,
(2)
[p, A] ls
[]p, Al - ltp,
llnearly (l
Al
+ p x > t ] . honogeneous,
: 0) ,
and superaddltlve. ( 3 )
[ p + q , A ] l [ p , A ] + [ q , A ] ,
whlch ehowe lt ( 4 )
to be concave.
Also
A c B + [ p , A ] : [ p , B ] Slnce
( 5 )
x e A : p x l [ p , A ] ,
the set (6)
a -
t" : px:
[p, A], p:
Ol
ls such that
(7)
a.e
Hence, by (a) and (7)
(8) But alao, (9)
[p, A] I tp, ,ij for
p : 0, by (1) and (5)
tp, Al = inf [px : x e A] = inf[px I
It
,
follons,
(10)
from (8) and (9),
: qx
]
[q, A], q I Ol
[P' A] thar
[p, A] = tp, nl
(p : Ol
p e 0rr
2E
Thus A = i that,
I t
w111 nosr be ehown
then A - i'
orthoconvex
A be closed orthoconvex'
has to be shorm now that
It
orthoconvex.
closed
A 1s closed
if
conversely, Thus let
it
A ls
tnplfes
A ls cloaed orthoconvex'
(6) that
fron
apPears lrmedlately
It
Slnce Ln any case A c i'
l' there
exl8tg
Thue p > 0'
Now
Then, elnce A ls cloeed convex'
Suppose * . I. p*0andCsuchthat
( a ) x ' e A : P x ' l C ( b ) P x < C Now slnce A 1s orthogeneous, that
ls
x e A r * t : * - x t e A , froro (a) that
follows
and non-empty,
lt
(a) shows that
[p, A] I c'
p > 0'
Hence, by (10)'
* . A o p x l [ p , A ] + p x > C
;
Thus (b) shows that
x e A, as required'
Itlsnowfoberemarkedthat,foranyA,Atsldentlcalwlth theclosedorEhoconvexclosureofA,thstiethelntersectlonofall closed orthoconvex
sets containlng
A, and contalned
containing
A, thls
belng cloeed orthoconvex'
ln every closed orthoconvex
aet contalnlng
A.ItJuSthastobeseenthatlfBlscloeedorthoconvexarrdB>A then B,
A.
FlrsE
it
has to be remarked that,
Br A+ i'
for
i,.
any sets A' B
29
(4) and (5).
Thls appeare fron B - B, go B: It x e I
t t
A, lnplles
has already
But lf
B le closed orrhoconvex,
A, ae requlred.
been eeen that
if
A ie closed
then there exl.sts p I 0 such that
follows
dlrectly
that
lf
for
[p,B] for all
p I0
.<:.
and
From this
[p, A].
A, B are cloeed orthoconvex
[p, A] Consequently,
px.
orthoconvex
it
then A - B.
any sete A, B [p, A] = [p, B]
for all
p:
O ..:.
= i
i
Theoren 9.1 For anv A . 0n and p e 0_ Le! [ p , A ] - l n f l p x : x e A ] and
I = t* : px: Then A l s orthoconvexr
the
closed
contatning
8et containlng
A.
[p, A], p e errl .
orthoconvex
closure
A, and contalned
of
A,
being
closed
ln every closed orthoconvex
A necessary and sufflclent
condltlon
that A be
closed orchoconvex ls A - A . Aleo,
for
sny A and p, Ip, A] = [p, a]
and for
;
any A, B a necessary and sufflclent
condltlon
that
lp, Al = [p, B] for
all
p e O- 1s that
A . B, so 1f A, B are closed orthoconvex
ttre
condl.tlonlsA-B. For any A c Qn and p e Q- lE is sald that l
x lf
[p, A] - px and x e A.
l
Thus the exlstence
[p, Aj has a solutlon -
of a solutlon
means
30
[ P , A ] = m i n l P x : x e A ]
is
even when the value
there is no assurance of this,
Generally
[p, A]
However, there ls the followlng'
finite.
Theorern9.2 If
A c Qn is closed then [p, A] has a solution
LetAbeclosed andp > 0' take any a e A, a > 0, so that
eA,
If0
pa > 0'
Then the set
p > 0'
Other$tlse
takex=0'
a minimum on lt'
is non-empcy comPact' so px attains
for all
[x : px : pa' x e A] But this
is
also a minimum of Px on A' EvidentlY,
for
anY ser A and P I 0' [p, A] = [P, inf Al
,
and hence
a = (inr n) Further,
if
[p, A] has a solutlon
x then x e min A'
Theorern 9 .3 If
solution
A c Qn ls
for all
and min A 1s bounded
closed
then
[p,
A]
has a
P e Qn.
For then rnin A is
comPact and
inf[px
: x e A] = inflPx
: x e min A]
=min[Px:xeminAl = m i n [ P x : x e A ] . Given an outPut posslbillty
set B c on and output prlces
o' e Qn , E h e u p P e r 1 l r n i t o f r e v e n u e f r o m o u t p u t
ls denoted
[ B , q ] = s u p l q y : Y e b ] = m i n [ t : y e B : q y : t ]
The cheory of revenue functions functions,
10.
nostly
derlves
from that
for
Cost
wlth obvlous adaptatlons.
Cost and revenue duallt
T h e o r e r n1 0 . 1 Ig!,4je91
palr
R, S lp, Ryl:
Ips, y]
Since pSo, necessarlly [pS, y] = 0, I 0, so in case Ry so that
[p, Ry] = -,
the lnequality
llow suppose Ry t 0.
is verlfl.ed.
Slnce R, S are duals,
xRy, pSq -
for all
px I yg
Hence psq .>
lnf [px : xRy] I yq
and hence 1nf[px : xRy] I
srplyq
: psql ,
ae requlred. Theoren 10.2 E
n, S are a polyhedral
dual palr
lp, Ryl and provlded
Ry la non-enpty,
[ps, y]
there
then ,
ex16t x,
xRy, pSq, [p, Ry] = px - qy Wlth such R, S xRY - (v3)1 > 8t'
bt : Y
p S q = p a : q b , all
elements belng teken non-negatlve.
Then
q such that [pS, y]
x,
q
5Z
[P, RY] = tnf[Px:
x > at' bt:
Y]
: bt 2 yl
= inflpat Also
[pS, Y] = suP[qY : Pa ] qbl The linear
Program max[qy:palqb]
is
since q = 0 is a feasible
feasible,
and only
bounded if
if
solutlon'
Therefore
it
ls
the dual problem, mln[pat : bt ] Yl
'
1s feasible,
which is when Ry is non-empty'
have optimal
solutions,
and the oPtinal
Then both problems
values,
which are [pS, y]
and [p, Ryl, are equal. Corollary.
Ry is non-ernpty for
bounded for
all
and only
lf
pS is
P : 0.
For, given anY P, [pS, y] pS ls bounded.
y I 0 if
all
is bounded for
Thls ls a speclal
any 1f 1f and only if
case of theorem 8'5'
Theorem10.3 For dual S, R 1f etther
of
then they both do and the optimal If
[p, Ry] has a solution,
[p, Ry], values
[PS, yl have optirnal solutlons are equal'
let
[p, Ry] = px, xRy . Then xtRy : equivalently, set [(xf,
y)
pxt I Px ,
the closed convex cone R > ls dlsjolnt : px'
. Px].
fron
the convex
Thence thele exl-sts u' v such that
55
but
(il)
9 = trv. lnplles
(1)
xrR : yr -
ux' I vy'
(11)
pxf < px :
uxt < vy .
lnplles
p i
Then (i), that
,
px - trux, I r 0, and that
lu,
wich rhe roontoniclty of R becauee 1t has a dual,
p, Q ] 0 and rhen thar psqt o
pSq.
Flnally,
wlth
xRy,
px > gty ,
whlch, wlth px = qy, psq, shows thar px = [pS, y]. argument, lf
px - qy, where
[pS, y] has a solutlon
By slnilar
then so does [p, Ry], and again the
values are equal.
11.
Conpound duallcy
Theorem 11. I If
R0, Sg and Rt , Sr are dual palrs (1)
min maxIqx : pSOg, xRt]l x q
(11)
r n a xm l n I q x : p S o 9 , x R r y ] = [ p S o S r , y l q x
provided in each equallty lf
then
=p, RoRr]l
that both sldes have solutlons,
and only if
elther
side does.
The left
of (i)
is nin[ [pSs, x] x =
nln[[p, x
=
mlnInlnIpz x z
=
rnlnIpz: xr2
=
ninIpz z
thle belng
: xRlyl
Rox] : xRlyl
(by Theoren 10.3)
: zR6x] : xRiyl
zRgxRly]
: zR6R1y]-
[p, RoRry] ,
T h e o r e m1 1 . 2 and conpact
For closed convex A . fJn not containlng the orlgln
x e A r P e B s u c h
B c Q , c o n t a i n l
tiratfi'0a!4 ( x e A , p € B )
p i l p i 5 p x Deflne B* c 0n bv
x e B * = p e B - p x < 1 so B* ls closed and convex. posltlve
ls bounded since B contains
AlSo lt
element' and contains
a nelghbourhood of 0 since B ls bounded'
Slnce also B 1s closed and convex, given f, such that x e B* wh1le !i Slnce A is
= 1, for sosre i closed
e B*,
r t i.
wlthout
whlle
loss in generallty
Othersrlse there 1s no essentlal
x e B*: But then,
since i
there
i*
follows
]
Thls completes the proof. is
that
n a x m l n [ p x : x e A , P e B ] p x m i n u r a x [ p x : x e A r p e B ] x p both exist
and are equal.
from B* for
I
that
P e B : P ; : 1
conclusion
> 0 such
I = 1'
I such that
exists
x e A +
e B*, it
i
A be replaced by Al
further
An equlvalent
exist
0, there
lf
al1
f, e B'
that
can be taken that
lt
lx < 1,
< for
fx
Atr is dlsjoint
alteratlon
and convex,
Stnce A and B* are closed
so also Fi = f.
follows
lt
and does not contaln
that AI cuta B*, say ln a Point i, all
a
, f, e B, and
35
If
Corollary.
Rg, 56 and Rl, Sl are dual palrs,
pso ls bounded and contalns contain
both
0,
exist
and are
and the
nin
max mln[qx q x
: pS6q, xRly]
rnin maxIqx x q
: pS6q,
equal
and posiElve.
there
ls
no ambiguity
A classlcal is
non-empty
it
is
if
a regular
and only dual
charac[erlzaElon a1l
bounded,
qolqq.l
relation
equivalently,
denoting
both
the
max
Rryl
homogeneous productlon
and does not
regular
ln
xRly]
max by l p S o'
S are
element and Rly does not contain
then
Accordingly, min
a positlve
and p, y such that
of
if
palr.
1ts
that
one which
regular
0 for dual
Then,
a regular
and again, is
contain
S is
palr
Ehe sets regular
and classical
Sectlon
thac
the
Sq are
and the
regular
Then,
regular.
is Ry,
R is
y > 0.
all
as seen in
dual
is
relatlon
that
8,
another
dual
xR,
case R,
pS are
non-empty. of
its
Ry
theoren
In
sets
all
by
1f
A
dua1,
homogeneous.
Theorem 11.3 If
R9,
56 and R;.
St are
regular
dual
palrs
and p > 0,
y > 0
then IpSoSr , y], have
solutlons This
and are
follows
equal
IpSo, Rry],
Ip,
RORiy]
and posltive.
by combinatlon
of
the
foregoing
proposltlons.
8.5
T h e o r e m1 1 . 4 I f R s , R t a r e r e g u l a r c l a s s i c a l h o m o g e n e o u sa' n d h a v e d u a l s and has dual SgSl'
Sg, St, then R6R1is also,
is nornal.
IE is already seen Ehat a product of nonnal relations t 0, Y ) 0' Thus R = RoRtand S6Si are both normal and, for P IP, RoRtYl
IpSoSt , y], both have solutions let
dual be S.
its
Slnce RgRl is normal,
and are equal and positive.
slnce [p, RoRtyl
Then [pS, Y] also has a solution,
does, and has the same value,
It
by theorem 10.3.
follows
thatr
a 1 l p > 0 , IpS, y] = [pSoSr,Y] for
y > 0.
all
theorem 9.1,
implies'
Since pS, pSgSl are orthoconcave this
chat pS = pSsSl
for all
p I 0.
Hence S = SOS1.
Theorem 11.5 product AB' (AB)* r
For anY A' B with Thus, by definltion
A*B*.
of A*, B*,
xAyBz, pA*qB*r :> px I iy so that,
of AB, A*B't,
by definitlon
xABz, pA*B*r : and hence, by deflnitlon
of
pA*B*r
Px Z tz
,
(AB)*, .:>. .<-
as requlred.
>=rz
xAi.z => px > rz . p(AB)*r ,
,
by
for
37
The followlng
ls an aLternatlve
If
A, B are regular
It
has t.o be shown that,
(2).
of theoresr 11.4:
homogeneoue then (AjB;:t - 4*g*
classlcal
for any given p, q,
xAyBz say (l):,
proof
px > rz
-.
(vq)pA*qB*r ,
(2) implles there exisrs y such that
The contrary ot
IpA*, y] < [y, B*r] Wlth A, B regular
classlcal
homogeneous,thls
Ip, Ay] . by theorem 10.3, whlch 1nplles
contrary
and thls followlng
to
(1).
wlth
,
there exlst
xAyBz,
px < rz
A*B* )
(AB)* ,
x,
z such that
,
Thua
the prevlous
glves
IyB, r]
is equlvalenE to
proposltlon
gives
the requlred
result.
The
lllustratlon.
For example, Iet
R - AI where xAt
= x > at'
tBy 3 bt
> Y I
then R* ! A*B* r.J,here p A * u = p a : u , u B * q = u > g b , 5o that pR*q
palr
pa : gb , in theoren 8.3.
arb e Qn deternines
a pair
of relatlons
A . en r 0m,
" 0D, where x A t = x : a t ,
From theoren 8.3,
t B x = b t : x
theee have duals A*.
On r On, B*.
Or r Qn where
38
pA*u=Pa]u, uB*P=u:Pb For producte AB and BA xABy=(vt)xlat'
b t l v
sBAt = (vx) bs : x'
x > 8 t
< + b s > a t when A, B are regular,
Then, by theorem 11.4, at least
products
are the correspondlng
the products
the duals of
BrtArt of the duals,
A*B*,
where pAtB*q;(vu)palu,u:qb <-palqb v
uB*A*v = (vp) u : pb, pa:
(A3)r. = 4*3*, Whlle A-B is
the productlon
between lnput gives
for
ln the von Neumann model, A*B* ls
and B*A* ls a relatlon
the dual relatlon
proflt,
non-poeltlve
and which
across any productlon
between actlvlty
a relatlon
to the next,
activltles
relatlon
= B*A*
These have reference
rate.
Then BA is
perlod. perlod
and outPut prlces
the lnterest
(Sl)*
of the growth rate,
which glves definltlon
that
seen directly
l-t is
In theorem 8.3 and corollary
vectors
from one
between shadow prlces
on
ln successive perlods.
Consldering
condltton
the regularlty
ln Sectlon
8, and the condltions
evldently,
for
the relatlon
sufflclent
for
(11),
and sufflcient
for
and fcr
(i).
(1) and (11) which appear
(a) and (B) on the natrlces
A, (1) always holds, A, (tt)
Thus (o)
a and b,
(cr) ls neceasary and
always holds and (B) ls neceasary
ls necessary and eufficlent
for
the
39
regularity
of A, and (B) ls slurilarly
hold, A and B are regular wlthout
the proviso
illustrates factors
L2.
tha[
for
1s sufflclent
regular
their
(a) and (B)
if
product AB.
However,
AB can be regular
whlle A ls noc regular.
Thls
the regularlty
of the
but not necessary.
factors
h o m o g e n e o u sp r o d u c t i o n
relatlon
R c On ^ 0n, lf
so xR ls conpact, p(x) =max[p:
exlsts
Therefore,
a product to be regular,
Growth and lnterest
ls
B.
which appears ln theoreur g.6,
For a classlcal it
and hence so ls
(o) does not ho1d, rhat is,
whlle
for
x > 0.
for all
Thls deflnes
xRxp]
the growth factor
for
quantlties
x.
Since p(xr) = p(1) lt
ls a properry
taken to deflne xR contalns
of rhe ray i
= [xr
the grolrth factor
a positlve
elenent
(l ' 0) , : .\> 0] Ehrough x,
on the rey.
Alao,
and can be
wlth
R regular,
x > 0, whlch ehorre that
lf
p ( x ) > 0 f o r x > 0 . Thus with duction lnputs
peri.d, for
lte
R as the productlon where the lnputs successor,
rhen Gale (1956), p(x) grow proportlonately groLrth rate
for
ls
relatlon
of an economy acroas each pro-
in one perlod are used to produce the
as consldered
by von Neunann (l9Jg)
E h e m a x i m u mr a t e a t w h l c h q u a n t l t i e e
fron perlod to perlod.
The upper l{n{t
al.l x > 0 1s denoted
P -su p [o (x):x>0 ]
and x can of thl8
40
Gale (195r') that wlth
be seen, following
rrtll
It
R regular'
o < 6 < . , and also p = p ( i l the llrntt
so in fact
f o r s o m e i > 0 , being attained
growth factor,
on some ray'
is
a maximurn gror^rth f actor, p-=rnax[p(x):x>0] By the limlt
total i
- growth factor -
: x' ""p[p(x)
be meant
will 0] ,
so o : 0 . Itlsthellnltoffactorsfortotalgtowth,lnvolvl-ngallconnodltles wlth
posltive
that
ls,
lt
It
quantitles.
n e e d n o t b e a m a x i m u mo f s u c h f a c t o r s '
need not be atEalned.
Whl1e p . ; n
p = p(x)
some x > 0 ,
for
for
; = ; , a sufficlent i,
though not necessary condltion
with R regular,
O.
p(x) > 0 for
S as the dual of a productlon
have interpretatlon
as reciprocals
that
6 = p(*)
for
to the dual
relation,
its
of interegt
S of R'
However'
growth factors factors '
An interest
rateforglvenprlcesofgoodsisdeflnedasrentontheworking capital,,
chat is
the inPut
cost,
sone
s o m ex > 0 ' s o p t O '
The sane concePts apply ldentically wlth
ls
ln a productlon
oPeratlon
which
4l
prevents positive lnterest
rate
profit
and permlts zero proflt.
correspondlng
to prices
(1 + i)px I py
p if
for all
Thus i
1s the
xRy implies x, y
wh11e (1 + i) Brrt
px = py for
some Xr y .
then
1+i=min[u:
upsp]
Thus, given that o(p)=rnax[o:pSop] ls defined,
as ic
is when S, and equivalently
R, ls regular,
i(p)=1/o(p)-1 has interpretation
as the rnterest
raEe for prlces
p.
Then the dual
maximum growth factor 6 = m a x [ o ( p ) : p > 0 j ls
thus the reclprocal
13.
Reciproclty
Theorem 13.1 If
of a mlnlmum interest
theorens
(cale)
R c Qn
" en is regular
classical
homogeneous then
p(x) =urax[;r: xRxu] exists
for all
factor.
X > 0, and if P = s u p [ p ( x ) : x > 0 ]
then
O . p . - , and
iR$
for
some i
> o
42
fhls
the theoren of Gale (1956) '
ls
To show i
. -,
so that
-r . + 0 since p > 0 and p"; = 1' *loi-t
follows
now by continuity
and contradlcts
that
st11L pr + -'
and P, * P.
such that * i.
pi
= r
there
- 1- n x i '
whlch by regularity
rt
lnpllee
0'
i'
(r - L,2r"
, so that
i
')
euch that px, -
I'
polnt
x'
the x. have a linlt
L - i ^ - -
t L ^
iRIi
> 0 such that
i
exiats
Then, as beforer
-
L - " a
a
1 { n { }
exl-sts a subeequence
- 0, and there
But the corredpondlng
But xlRxlor,
Slnce xioi
> O.
a sequencex.
Ttrus, there exlsts
*i
thac G'i,
remalns to show that
It
*.kro,
i
'
rhen pi - 1r eo
For the corresponding subsequence o| of the 0r'
> O.
i
* i'
and a subsequence xf such that x'
i,
(r + -)
px = I are cornpact' ao the x. have a llnlt
But the x > 0 such that point
xrRxrga, 9, * -
= l, ] o, Pxr
*,
Take any p > 0'
f, = -'
that
and g, such that
r = Lr2r..'
xr'
Ihen there exists
posslble
suppose if
subsequence p' - 6 , ao that
and hence by contlnulty
x'pr
+ [f,'
inip'
Theoren 13.2 E for all
R, S are a dual palr
wlth
grovth
functions
p, x p x > 0 - o ( P ) P ( x ) I 1 Since xRxp(x),
pSo(p)p 1t follors px :
o(p)pxp (x)
for all p, x. Corollary (1). Corollary (1i).
=o 66 . t. Fi ' o ;P : l ,
that
o p : 1 .
'
p(x),
o(p)
then
+J
Forallp. for
p there existsx>
some F r O. p . i,
for all
Bur now i* ir
follows
0such thaExRxp. A1so6= o
r 0, so rhar op I
rtrat o-6 . 1.
l.
Similarly
rn the next theorem these inequaritie"
.t.
Since thls io :
holds
f .
"ar"igthened
to
equalitles. Theoren 13.3 o o = l , o g = 1 . For any U ' 0, consider G where x G y : x > y r , with
dual
H where p H q " u p : q
Then
R n Gr * 0 <:
u < p
i n E R n G r r 0 < - r . p Siml1ar1y s n H r r o < - r - 1
: o - ,
i n t s n H r * 0 < - u - t . ; . B u E , b y E h e o r e m8 . 6 , R n G ' = 0 < - i n E S n 1r *1 0 r so p r [ . - p - l . 3 , equivalently
3; = 1, similarly
Corollary
(i).
Corollary
(il).
op : i
f,
= J .-
;i
o-i
= 1
, 0 :
op = f
op = f .o
The theorems of Ehls secti.on will to the von Neumann roodel.
i
= obe ilrustrated
by applicaclon
L4.
von Neumann 4949-l n LeE ar b e 0n be a glven palr
order nxn.
of matrlces'
non-negative'
of
Conslder the condltlons
(s) t > 0 -> at 2 0, ( B ) p > Q = + P b > 0 , (Y) a + b ' 0, to
where t e Om, p e Qr.,' They are equivalent (a)t
p t 0 o
Pa > 0
(3)'
t > 0 - = >b t > 0
( t ) '
P > 0 , t > 0
Also consi-der the relations
P a t * P b t> 0 '
:
R t Qn " Qn' S t Q'
Qr',where
xRY - (vt e Qm) x > at, bt : Y p S q . p a l q b Thesearebothclassicalhomogeneous.Intheorem8.3theyareshown to form a dtral Palr, s = R *
R = S * .
For the condltlons M ( R ) . o R Y - Y = 0 W(R) = (vc, Y) xRY, Y > 0 defined on R, and similarly Yl(R) <w(R) <=
on S, direct (:)
<:
!t(S) ,
(ts)
<-
u(S)
Thus M(R) <= and the saure with
inspection
W ( S )'
R' S lnterchanged'
shoersthat
45
Theorem 8.5 glves chis concluslon just
as a consequence of R, s being
a dual palr.
for R is defined as the
The regularlty
condition
conJ unct ion .V(R) ^ w(R). rt
appears equivalent
condition
for
the condition
to the same condition
R, S ro form a regular (o) '
on S, and provides the
dual pair.
The conjuncEion of
(B) has been seen co provlde thls
conditlon.
T h e o r e m1 4 . 1 R, S form a dual pair, and (B)',
for which (o) and (B), equivalently
(o)'
are the regularlEy conditions.
v o n N e u m a n ni n t r o d u c e d s u c h a p o l y t o p e p r o d u c E i o n r e l a t l o n derlved from a marrix pair
(a, b),
and also the condition
subsequently considered any classical with
the regularity
expllclt
ln lt,
v o n N e u m a n n r sd i s c u s s i o n ,
from it
with
Though thls
condltlons
As wlll
relation
is not made
are arso relevanr
to
lerma, and also to connectlon of
the growth and interest
which otherwise comes imediately,
Gale
be seen, the relevance 1s both
E o t h e a r g u m e n Ew l t h h l s t o p o l o g i c a l the result
honogeneous production
condlt.lons r. and w.
theae regularity
(y).
R
interpretation,
when che theorems of section
13
are used instead. Here the Gale conditions relatlon
have been identlfled
the symneErlcally whose regularlty
related
applied wlth
rhe condiclons
dual relatlon
ls equlvalent
to the von Neumann polytope (o),
(g).
has been brought
to regularlty
for
into
the orlglnal
Also, vlew, relatlon.
46
they can apply to R, S thus derlved
of relations'
subJect to the condltions
(c) , (B) '
pursued now, and the role
of the further
b)
be
wt1l
The appllcatlon condl'tlon
any (a'
fron
palr
dual
any regular
13 concern
the theorems of section
slnce
('f) w111 appear'
especlallylntheoregrl4.5.ThlscondltlonhasacrltlcalPartln vonNeunann|soriglnaldlacuasion,andherettwlllbeconnected vlth
form of condltlon
the broader
and then enters
lnto
t o whlch arLses ln theorem 13.3
theoren 14'5' from (a, b) detelolne
R, S derlved
The relatlon
ii
6 - " u p [ p : x R x p , x > 0 ] 6 - s u p [ o : p s o p , p > o ] and aleo
ol
&-".rp[o:psop,p>
0l
of von Netnann lnvolve
The reeults recovered
p-".tp[p:xRxP,x>
wlth
together
theorems of
sectlon
further
6 ana 6 '
theorens
Then von Neumannrg topolo8lcal
basls.
lnvolvlng
13, whlch have convexlty
nolr be
Theee wlll p "na
and llnear
uelng
the
eeparatlon
ae
i,
have a review,
argubent wl1l
inwhlchtherelevanceoftheregularltycondltlonewlllbedealt with.
Flnally,
a flnite
algebralcal
lndependent
of both sectlon
the reeulta
agaln,
rnethod w111 be used, which Ls
13 and von Neumannrs approach but ylelds
and aleo leads to further
theory
on compound Srowth
and lnterest. ThevonNeumannnodelwillnowlllustratethetheoremaofthe prevlous
sectlon
vhlch
are appllcable
to any claeeical
homogeneous
47
relatlon. apeclflc
But the epeclal feeturee
nethods shonn later
explolt
the more
of the nodel.
Glven R, S derlved
fron
(a, b) eubJect to
14.1 sh@re theae are each regular
claealcal
(o) and (B),
theoren
hooogeneous relatlona.
llence by theorem 13.1 (Gale), O . p - .- r 0 < o - .- ; alao p- and d, rtrLch are deflned hlve
aa upper ll-Elts,
are attalned
and
naxina. Thue theoremg 13.1 and l4.l
glve:
Theoren 14.2 (a) end (B) lnplv 0 < ; < - r 0 < o - < -
end
6-naxtp:xRxp,x>0] i-naxlo:pSop,p:O]. Let C . [ p : x R x p , x > 0 ] a n d
t t - [ p : b t > 8 t p r r > O ] .
fheoren 14.3. G c llr and (a) 1npl1ee G - H Suppoae g e Gr that
is xRxp, x > 0 for
x > at, bt > xp , for
eome x,
t.
Ttren, provided
p > 0,
bt > xP > o ao that
t > o.
Arao
x > 0
aone x, equlvalently
b t > x P : a t p r so that bt I atP. Thus, for
g > 0, P e G iraPlles t 2 0 ,
b t > a t P '
( * )
Stnce0 eHnGit
eH'
that lsp
f o r s o m et '
Now suppose 0 e H, that x = at,
condltlon
(*)
is
(o) gives x > 0'
for
i s c o n c l u d e d t h a tG c H '
some t'
Then' taking
Thus
x > a t r b t : x P r x 2 0 , shons that
P e G, and hence H c G'
is equlvalent
Sl-nce in any caae G c H' thls
to G = H.
Theoren 14.4 (s) and (B) lnPtY 0 . p- . -,
0 < E < -
and
6 - r " * [ p : b t ] a t P , t > o l o-- nax [o : pa: This follows
opb, P > 0]
by comblnation of theorem 14'2 and 14'3'
Theoren 14.5 (y) funplles that,
for
all
x and P,
( 1 )
x R x P , x > 0 r g > 0
(il)
pSoq,P>0,o>0
and
lnply
(111) px > 0
49
of R, (1) 1s equlvalent
From the defi.nitlon (1)' for (1i)
some t,
x>
at, bt]xpr
and thls
x)
t > 0.
lnplies
Eo
0,pt 0 A1so, from the deflnitlon
of S,
is ( 1 1 ) '
and thls
p a > o p b , p > 0 , o t 0 ,
lrnpiles pat>opbt>opatp >0 pat = 0 is inpossible,
From thlsr
also pat = 0, contradlcting
for with
o > 0 lt
would lnply
(y) since t > 0, p > 0.
and slnce x > at frorn (1)'
lt
Thus pat > 0,
folLows that
p x a p a t > 0 , showlng (li1). Theoren 14.5 (c),
(B)
?nd
(.r) lnply
(1)
66-r
( 1 1 )
; = ; ,
and also
Fron (c) posltlve
; - ;
and (B) lt
has been concluded thet
f,, 6 are flnlte
and
and also xnxd,
x ) 0,
pSEp, p 2 0, for
some p, x.
that
px > 0.
concluslons
By theoreu Flnally,
follow.
4.4,
from th18 nlth
(v)
frorn theorero 1.3.3, Corollarlee,
lt
la concluded the requlred
50
nlght gror
to actually
be unable
aluuJ,taneouely
that,
though some gooda
the rnaximrm growth p-, all
etteLn
et any leeser
rate,
horever
for
polytope
theorem 1s proved again
Thla
6 - p f"
of the conclualon
The luportance
close
can
to f,.
correspondences
ln
algebra.
theorem 16.2 by flnlte Theorern 14.7 (c),
( 1 )
of p, t and u such that
('1) ftnply the existence
(B),
b t > a t u , t 2 0 ,
(11) pb
Such u le unlque,
and moreo]er_'
(1v)i-u-d-l ls
Thls eseentially argunent
will
be glven
of von Neumann (1938).
the result
ln the next
section,
Theoreme 14.4 and 14.6 (1) glve The argunent recovers
of von Neumann, leadlng
theorem 14.4 ae an l-nternedlate, lJlth
(1) and (11) wlth to the laet
of theorem 14.2'
the conclualon
with
18 ae folloss.
any I such that b t > a t l , t 2 0
deflnlng
a grohtth factor,
and any v such that
pb < vpa, p > 0, an interegt
factor,
lt
Hls
appears that
v D a t > p b t > p a t t r a> 0 .
part,
u as ln and whlch
the concluelon
of
(1v).
5l
Then pat = 0 ls
finposslble,
a contradl-ctlon
of
every l-nterest and (tt)
(y).
factor
1np11e8 also pbt - 0, glvlng
slnce thla
Thus pat > 0, and hence v > I ls
at leaet
every grorrth factor.
u appears as both a grorrth and an interest
follows
that
the nlnlnuq
lr 1s slmultaneously of lnterest
Fron thle
Whlle theoreur 13.1, of Gale (f9s6),
general{zes
a further
po - f.
relatlon
p- -i
result duallty,
lt
does thle
the more generally
15.
present
duallty,
valld
p-ri -1,
relatfone
factors
theoren
and
13.3
wtrich produces the
the addltlonel
ln McKenzie (1961),
ln the duallty
If
extenda an aapect of the
wlth
aleo glves baeie for
It
factor.
nust be unLque.
aapect dependlng on duallty
already
but
le unlnvolved
lt
(1)
But in
the maxlmum of growth
factors.
von Neumann cheory whlch
Accordtngly,
klnd
of
not dependlng on
framework wtrich here provldea io - l.
TooologlcaL oethod The folloving
lntereectlon
(1938) and used to obtaln
for
hls
economlc nodel.
V are compact convex and E, F S c U x V are cloeed and
I!U,
the seta xE, Fy are non-emDty convex for
xEy, xFy for Corollary
results
(von Neunann)
Theoren 15.1
such that
theorem rraa proved by von Netrnan
all
x, I !!gg
eoqe x, y.
(Kakutanl).
and euch that
If
U is compact convex and E c U x U ie cloaed
xE is non-enpty
convex for
a1l. x then xEr &_.g
x.
For take V - U and xFy = 1 - t. Kakutanl
(19+1),
after
giving
a sLmpler proof
of the corol,lary,
52
deduced the theorem frorn lt.
Ihus,
given such E, F let
W- U x V
anddeflnel6l.lxWby (x, y)T(x', Then T le closed
= r'FY ^ xEYt .
I')
and (x, y)T - Fy x xE (x, y)T(x,
ie convex and hence, by the corollary, eome xr Y.
xPy, xEy for
The proofa polnt
y) and equlvalently
theoren
of von Neumann and Kakutanl
depend on the
both
fLxed
of Brouwer (19)9).
Aa an appllcation
of von Neunsnn's
theoreD Kakutanl
deduced
the foLlowing. Theoren 15.2. If valued
U, V are compact convex and f(x, on U x V euch that
functlon
le a continuous
ly :f (x' Y) I tl
then
max min f(x,
-
y)
nln nax f(x, yeV xeU
xeU yeV Cloaed E, F c U x V auch that
xFY = f(x,
by von Neunannrg theoremr rnaxf (xr, mln ytEV IteU
But in
any caee
Y) '
nax f(xt, XreU
xEy, xFy for
y')
Y)
xE' Fy are convex are deflned
xEy = f (x, y) - roln f(x, yt ev
Ilence,
real
the setg
lx : f(x, y) : tl, are conver
y)
(x, y) -: -1 f
by
Yt)
Y) .
eome x, gax x'eU
y.
Then
mln f (xr, YteV
Yt).
53
mln max f (x, yeV xeU
y) > max ml.n f (x, xeU yeV
y)
.
For let g(x) = min f (x, y), yev
- rnax f (x, y) xeU
h(y)
,
80 that e(x)If(x,y)jt'(v) and hence < urln h(y) yev
nax g(x) xeU Thus the theorem ls proved. functlon
It
ls valld
le in the cloeure of the real nunbere.
Another statenrent of the concluslon a eaddle polnt,
that
iB there exlet f (x',
for all
x',
the functlon
x, y such that
f (x, y) : f (x, yr),
can have at most one eaddle-value.
be two saddle polnts,
For let
that is
g(x, yo) l8(xo,
t;,
g(x, yr) : g(xt, y) , for
all
x, y.
Then in particular,
g(xo, yo) 5 S(xr, yr) j and elmilarly
has
y) 1s a saddle-value.
A functlon yi)
y) I
le that
y'. .
Then u = g(x,
(xr,
also when the range of the
wtth 0, I
g(xr, yo) I
interchangerl, so rhat
gix,r,yc) = g(xt, yt)
.
a(xo, y0),
(x0, yO),
54
order
Thua, wlth
1r, Qn.
of
by row vectors
end sun to 1: end let
ere non-negatlve
m where elements
be sinllarly
in 0r, described
(n-l)-eftop1ex
Let U be the
J e Qo, I e 0n havlng
elemente
V all
l, U = [ p : p e 0 r r , p I - l ] ' v - t t : t e f , l m , J t - 1 ] Any p e 0o where p > 0 hae a normaltzatlon where the ray through p cuts u.
the polnt t(Jt)
-l-
(pr)-l
P e U, whlch ls
slnllar1y
any t > 0 glves
The sets U, V are compact convex.
e V.
Conslder - pbt/Pat
g(p, t) It
deflned
ls well
not both pat ! 0 pbt = 0, and thls
provlded
asaured by the condltlon
(P > 0, t > 0)
(v).
It
le hoaogeneoua of degree zero and
thue he6 the Bam€ valuea when p, t are replaced ln U, V. lt
True,
lt
ls apeclfled
ls
by Juet ite
by their
normallzatlon
valuee on U, V'
Aleo
18 contlnuoua. For0
ls
t) :
u
to
equlvalent
p(bt-atu)>0 It
followe
that,
for
all
u and t ' the set
[p: ls
convex.
Aleo,
lf
and only
lf
for
g(P,t) > u]
glven p and t,
bt > atu
thls
conditlon
holde
for
all
p
55
Stnilarly
the setg : t(p,
lt are convex. all
t lf
Also,
and only
for
t) :
ul
given y, p the condltton
g(p,
t)
:
u holds
for
lf pb . Upa
Ttle condltlons that
f(p,
thls
concluelon
t)
of theorem 15.2 are satlafled,
has a saddle polnt ls equlvalent
(p, t),
with
the concluglon
and eaddle value u.
to the exletence
A1eo,
of p, t and p where
p e U r t e V a n d 0 < ! . such thet b t > B t u , Thls laet le that
concluelon
p b < u p a
correeponda to that
the condltl-ons
(c),
the denlal'of
the denlal
of
(c)
and lmedlately
here becomee ldentlcal The result
But it
le equivalent
(B) le equlvalent
theee trro apeclal
nith
that
of the foregolng
to a saddle velue
ro a saddle velue verlflable
lnpllee (1)
le well
deflned. ( 1 1 )
t ) 0
p b < u p a ,
p : 0
and
u - O.
Putting the content
in theoren 14.7. dlecuaalon
1.8 stated
(p > 0, t > 0)
and has a saddle polnt. b t > a t u ,
here,
u r o, Eod
caseg aslde,
the functton g(p, t):pbt/pat
A dlfference
can be eeen dlrectly
Theoren 15.3 (y)
14.7.
(B) are not in the hypotheale
0 < u < - le not In the concluslon. thet
ln theoren
Also
aa fo11orr8.
t6
are the condirlons
a 6add1e-point
for
(p'
t)'
u'
4.saM
von Neunsnnpolnted out that (.r) assuresthe functlon glven bv(r)lsrrelldeflned,gndalsothatcondittons(11)arethecondltlona forasaddle.polntandseddle-value.Itcanbenotedthatthe ldentlflcatlon
(il)
of u in
a saddle value lmredlately
with
the uniqueness of such ! '
establlahee
Theorem 15.2, which Kakutani obcalned as a consequence of
to establlsh
applled
thle
Instead
route.
dlrectly,
of a saddle-polnt
the existence
he proposed to uae his (for
oethod
by the followlng
of Ehe functlon, follow
But von Neumann dld not
(tl).
to
end hence of a solution
has here been
theorem 15'2,
theorem,
von Neunannrs intersectl-on
lntersectlon
theorem
whlch a rnodlflcation
is
necessery) . ConelderE,FcUxVwhere pEt = bt
' Pbt - Patl
> at^
Pbt '
pFt = Pb 5 vpa, o, u belng
vPat
'
Thue ln pEt'
deternlned.
finpllcttly
'
wlth
a(i
ros I of a, flret o{, and then,
t 3 t(l
t^
for all
i
becauee P > 0, neceasarllY - a{ttr
for
r - nh[b11
t/a(lr
blrt
sone 1'
Thla glvee : .1t
r r 0]
,
dependlng'"' r";:'= 1", ;.;'"" =
[ p : b (r 1, t
> 3 / - t (1
I o
- 0 ] , p - r.
denotlng
5'.7
that
16, Et ls
the face of the slnplex
such that br, t t a/{ tl. (1 (1 for
some 1 lt
Thus Et is convex, and slnce b,. (i
ls non-empty (There ls difficulty
ln whlch case tr = -). slmilar
Grantrng al.so that
discussl.on holds
conditlons
U on which pt = 0 for
bre present
conclusLon that
(lt
for
does not)
an appllcatlon
E n F * 0r that
since pbt - patl
l,
ls applicable
Thus pat > 0.
Then fron
only lf
and that
.I .
a
of theorem 15.1, wlth
v it
ls
so rhen also pbt - 0, glvlng
(Thls argunent
t- - -a(, r- t-
F and the seta pF, the
ls pEt, pFt for
For such p, t and the correspondlng
1
here when at = 0r
E is crosed,
for
all
I < -r
the
some p, t. lmpossible
a contradlctlon
or sirnllarly
pat - o,
that
of
(V)
v < -).
patlBpbr=vpat lt
l - v.
follor^rs that
Such p, t therefore
glve the requlred
concluelon. Modlflcatlons where there
can uake good the defecte
le vlolatlon
(c) or
of
(B),
that
in thla
and then renolnrng
are satisfled,
Wlth (o) (a1so requlred
deflned,
convex and non-empty.
closed.
For,
pat > 0.
In thls
for
r ( -,
Also lt
reoarked,
wlth
case PEt <-
bt
are for when (c) and (B)
the identlficatlon
ls assured that
as already
They can be treated
(y).
together wlth
fron theorem 14.3) lt
conslderatLon
cases
le where at r 0 or
pb = 0, admlt an lndependent elementary account. separately'
argument.
> at Pbt/Pat,
[,
and the sets Et are well-
ls readily (y),
of p wlth
verlfled
that
E ls
pEt where tr < - funplles
58
the condltlons
(o),
the seta PF are non-empty for oo:) sone V, b.r
for
denotlng
I
(B) and (v),
there
le no aasurance that
Ttrus' pFt requlree
p'
all
the argument 18 that'
through
to carrying
lnpedlnent
Another even wlth
ls
E ls cloEed'
that
imedlate
lt
on both eldee of the lnequallty
contlnulty
and then froo
all
vPaJ) for
I ' tt
ln whlch caee pF i8 etrpty'
eoue J, no such v exlgts,
= 0 for Da., ' J) Inetead,
E, F c U x V be consldered
let
, Pbt '
PEt = bt ] "tP
> 0 whlle
But ln caee pb''t
columr J' of b'
J t
'
PFt = Pa > oPb, Pat
where
PatP' Pbto
HereElsaabeforebuttherelsanodlflcatlonlnF.Nor(c)and
Then theorern 15.1 can be applled
sete pF.
9 ,
o
pFt for
pEt, < -
E and the sete Et'
(B) and ('r) give the same condltlona
and, ldentlcally,
that
for
condltlons
give the requlred
(r)
some P' t.
pbt - PatP, Pat ' thls
oPbt
lnPlles pat > 0, Pbt > 0.
Also pbt - PatP vhlch,
vlth
Pbt > 0, lnPll'es p o - 1 .
Thue, with
u where
for
F and the
to glve the conclualon
For such p, t and the correepondlng
t
Wlth (v),
aa before;
'
oPbtP ,
59
-I P
p, t give the requlred the addltlonal 0 < !r < -,
16.
!
-
o
,
conclueion.
hypotheeis
(o),
Thls provee theoren 15.3, wlth
(B) and the addlrional
conclualon
as requlred.
Algebraical
method
Conslder a palr wlth
t
elenents
of matrlces a, b e en, rhat
in the non-negative
number 0; and condltlons
( c ) t > 0 - a t > O ( B ) p > 0 - p b > O (v) t > 0, p > 0-
par*pbr
> 0,
where t e 0m, p e 0r, i equlvalently p > 0 -
(c)'
pa > O
( g ) " t > o - b t > o (V)' a*b
> 0
Let f - e u p l t : b r > a t l , r > O ] , J - l n f l v : p b < v p a , p > O l , and i = s u p l l : b t > a t l , t r 0 ] , v - i n f [ v : p b I v p a , p > 0 ] , eo in any caee ^ . lr Obvlouely (B)'
+
i
' 0
(o)t
:
i
. -
u :
v
is of order D x tr,
Thus ( c r ) -
v < v < -
( B ) - s . i 5 I Also,
I and P' v
anY t'
for
b t > 4 t t r , t t 0 pb-. Pa, P>0 implles 0 < patl Thus pat = 0 inplles (y)
irnplies
< vPst' :; Pbt
also Pbt - O' glvlng
Tttle thoets thet
u'
pat > 0, end then f:
a contradictlon
(.r)-^:i, provlded
i
. -.
But thle
The follotring
18 true
ln any caee lf
hae been Proved'
Theorem 16.1 For anv a, b
i S ^, u : i , ( o ) - - v t -
(B)==-i'0, and ( v ) o I S r , so ( o ) , ( B ) , ( Y )-
o ' i :
Nolr the followlng
wlll
Theoren 16.2 For any a, b
^ :
t :
be shosn
i ' -
'
; - -'
of
(Y)'
eo
6l
i : I ,
i : ,
( a ) - r - 1 , ( g ) : i = u It
glves an algebralcal
result
proof
ln theorem 14.6.
Lenuna.
For_-ry.
for
polytope
The followlng
correspondences of the
1s requlred
a, b and Lr bt > atu for some t > 0 or pb . upa for
(1) elther
some p 2 0
and not both. (11) either
bt > atu for sone t > 0
or pb < lrpa for
some
p > 0 and not both. Thls
follows
from the theorem that,
ct > 0 forgomet >0orpc for
(1) take c - b - lar Flrrt
lt
(c) lnpllee,].
for
u for sone lr.
Thus
replace c by - c'.
(il)
w111 be shonn the (o) lrpllee "o,].
c, elther
<0forsomep>0andnotboth.
and then for
-,
any matrlx
i:
r.
By rheorern 16.1,
By deflnltlon
of i,
for
any ltuch U. p b : 1 , ' p a ' p t 0 , for
eome p and ut where
u , u ' 3 , l. But (o) lnplles follorre
pa t 0, slnce p > 0.
Wlt.h thls,
and y > ut lt
that p b < y p a r p > 0
But thl6,
by the Lema,
lnplles
that
b t > e t u r t ) 0 le lmpoeelble tt
for
ls Bhoun that,
all
t.
for all
By deflnltlon u, u t i -
of f thls ,:
i,
lnplJ,es tL : I.
end Ehis
Thus
.
lmp1les v:
:
A.
will
trow lt
be shown that
l-n anv case v i
there ls nothlng more to Prove' So suppose f let
u > f.
Then, from the deflnltlon
of I,
< -' for
all
I
lf
and t lt
ls
inposslble
that b t r a t u r t 2 0 . Hence, by the Lemta, pb < ;rpa, p > 0 for
some P.
But Ehen J.nnedlatelY p b < u p a r p > 0
for
by the definition
some p, and this
of i
lrnplles u l;'
Thus
p t f > r l ; , and hence ^ : t. Theproofoftherestofthetheoremcorresponds,wlthobvlous modlficatlon. Corollary.
For any a, b
i : ^ vrr V",g9j]g9i:I, V
<
V
and ( a ) - ) = v < - r
( B ) : 9 . i = i , ( y ) - i = r = i = i , so also (a), (8) -
0 < X
= v < 6 = v 5 I
I = -
63
and
0. i =; = n = 'l . - .
( a ) , ( B ) ,( y )Thls follows
by conbination
wlth
The nexL cheorem shows thac f,
the prevlous
theoren.
defined as an upper 1lnit,
aEEained and thus a maxlnum, and correspondlngly
for
ls
v.
Tbeorem 16.3 =tI- .,
Ior
If
b
(1)
b*
(11)
pb 5 ipa,
p > 0, for sone p
I - 0, then (1) ls validated vrich any t 2 0.
since (o) lnpliee
(1).
-,
I'.
(a).
of
a vlolation validates
, t 2 0 , f o r s o m eE .
arf
by theorem 16.2, Corollary,
That ls,
To prove (t)
remalns now
I = - then,
there must be
at = 0 for some t ) 0. it
If
Any such t
to conslder the case
0 . f . - . LJith ; < -,
the denlal
p > 0.
has a solutlon
But, nlth
of pb < ppa for some p .6, bt > atp has no solutlon have such a solutlon, Thus the denlal Corollary. t,
of (1)
of (1),
by the Lema,
6 t 0, thls
then le also a solutlon
and, agaln by the Lerma, this
t > 0.
But wtth p.;,
by deflnltlon
of f,, so there ls a contradicElon.
For any a, b the conditlon
(1) lnplles
p and p such that
and also that
b t > a t u ,
t z 0 ,
p b : ! p a ,
p z 0 ,
such u is unlque,
fuoplles
Ehls [lrsE
The proof of (il)
is false.
pa < 6pb
lnplies
and (c)
lnplles
1s slnilar. that
there
exlst
64
;r > 0 .
u < - and (B) lmplies
wlth
the
y where
and taklng
to theorem 16.2,
corollary
by conbinatlon
follows
this
the uniqueness,
But for
I = u = i , slnce f = i, ls
Thus, wlth
-l',
i
: v p , o a] p r b , defttted
deflne
2, ...
btN > at1l,
I * - s u p [ l : b t 1 , =^ t 2 , . . . ,
= inf[v
of von Neumann'
and compound factors
For any a, b e Qn and N = l,
i*
and
14.
shown at the end of Sectlon
Gap-cycles
such v is unique,
by the argumelt
ls best establlshed
thus glven,
already
17.
That (V) lnpUes
sub1ect to (f).
tl
] 0] ,
pN-la I PNb, pH > 0l
...,
the case N = l
as before,
glves
I, - I , i, = ; Stnce bt > atl
glves also btr > atr2,...,
lt
follows
bttrN-l r at trN,
that
t'
N r =T '
N i
and siurilarly - - N u N I u Since, from theoren 15.2, corollary, Theorem 17.1 For anv a, b and N, N u N < v
: N < A
i l n N
i:
I
' the follorrlng
ls obtalned'
65
(Vn) wlll
A condltlon ldentlcal
with
be shonn whlch ln case N - I becomes (y).
the von Neumann condltlon
15.2, corollary,
lnplles
Neunann theory,
(v*),
and (B) lnplles
I,
f = i,
together
= in,
this wlth
Wtrlle (V), by theoreur
belng a maLn reeult the regularlty
of the von (c)
condltlons
and hence, because of theorem 17.1, alao
I - J , and at the saxoe ttne : : N ^N=^ ' Thls last
reeult,
productlon
growth,
le re-establlshed
theory
theorero" - that
type of "turnplke
for nore rapld
perlod
- N uN=u
when put in a growth and lnteresc
expreas.ea a modlfled no short-cuts
-
or greater ae a block
proflt,
context,
there
are
wtren the
of N origlnal
perlods. Ttre von Neunann condltlon (v)
for
sir
> 0 or Ora , 0,
r every good la elther
For an ordered palr 8ap If
lt
ls a + b , 0, ls restated
to
every good I and baelc actlvlty
actlvlty
that
> 0 a. +b. 1r 1r
and le equlvalent (y)'
(y),
ls nelther
second, that
r.
ln every baelc
an Lnput or all output.
of activltlee
an output
That ls,
for
(r,
the flrst
e),
a good 1 deflnea
nor an input
for
a
the
ls
orr'o'"i"-o Then a gap-cvcle
ls deflned
by a cycllc
a gap between every succeselve pair.
aequence of actlvltlee
wlth
66
It
a gap-cycle
provldes
goods i,
J,
...,
(q, r),
that
ls
the succesgor of q is
that
k whlch aPPear as gaPs between (r,
b1.-o'
O n O- 0 ,
that
...,
rr 8'
for aII le,
remalng unaltered
(H)
( a ) ls
aleo for
The part
The condltlon Ls self-dual'
k'
between goods and activltles
condltlon
by whlch lt
roles' (G) ls
for
condition
the regularity
of the conditlon
condltlons
(G) whlch
or of goods, where there
of actlvttles'
interaedlate
..',
a > 0 a n d b > 0
eufftclent
ldentlcal
to the condltlon
a > 0 or b t 0, stronger
and the etlll
0
when theee exchange their
An obvioue eufflclent
""
* an. > o
...
q and 1, J,
hae I syurctry
lt
t)t
"t.'
la equivalent
* oJ" *
(s'
J J
J O
(G) brr *.1"
s)'
"1"=o 3.. - 0
b.^ = 0,
The abaence of gap-cycles
f agein'
sequence of
cycllc
ls a further
there
if
sequence of
q represent a cyclic
understood
belrg
lt
actlvl-tl-esr
...r
..tr
s'
rr
Then let
wlth
the von Neunann condltlon
betlteen
(c)
applles
le a slngle (Y),
and (8).
to cycllc
sequences
element ls
eo (G) te a condltlon
(H) end (Y) '
(H)e(c)-(y) Let
('y*) be the part
of the condltton
(G) whlch appllee
to
67
cyc1lc
sequences of N elenento,
ao (G) ls
the conJunctlon
of
(y*)
for al1 N,
(c) <: repeated
Since
elements
are
(v*) -
(nu) (vno) permitted,
(vn) tf tt . lt
In particular,
(v,)= (r) and so (vr) Whlle (G) is f = i ^N,
wtth
(v)
than (y),
stronger
together
-
further
for
all
N.
and glves the ysn Neumann concluslon
concluslons
about compound factors
vN the dleJunctlon (f)
= (vN) (YN)
ls weaker than (.r), (y) +
(f),
glvea the von Neumann concluelon.
but stlll
The theorem whlch consolldates
the above renarks
1g ae followe.
T h e o r e m1 7 . 2 For any a, b and N,
(c), (B) (v*) > Assuming (a) and (8), ( 1 ) for
some l,
v.
(11) for some tI
I* I i* .
suppos" i,
. I*
Then
O I i H < v < t r . I n I Now tr < f*
from (1) tnplles
bt1 > at2, btz I ar3, ..., btN I ati l,
, ...,
c* e Qm. Also i,
< v impliea
t1 2 0,
68
vPna I Pl b, Pla i
(lil)
tt
> 0-
btN > 0D
at1 tr> 0+
att > 0'+
and I > 0 frorn (i)'
(o)'
Fron (11)t wlth
P,, e Qo'
...r
for somePl,
P N - 1 8I P w b ' P N > 0 '
Pzb, ""
tN = 0
and then aN = 0 -
> O+
.tN
baN-l
= 0 +
> 0
t"-,
and generallY .1_1z 0. (1 '
ai - 0: It
N)
2, ...'
that
follows
Sln11arly
tt,
fron
(111), wtth
(v) Alao fron
pI,
an = o
...,
(1v)
...r
(B) '
P o l> 0
(11) and (111) ' (vl)
vpNatl I prbtt
I Prat2 I Pzbt2
:
...
. . . i n * u t * : p w " t rr : o , ao (v11)
vPnatl
i
But wlth
v < I and P*at1 > 0,
But thl8
lupllea
every
(vltr)
plbtl
But from (1v), tl, r,
6, ...,
t.
- Pratz
Also fron
br, gtvLng a contradictlon
(vlt)
term ln
"1" of
ls
zero.
only lf
Pnatl'0'
Hence P*btn - Pnatt
- P2bt2
(v) pr t P2t ..., k.
...'
(vl)
ls poaslble
tN each have eomeelement Posltlve'
t2,...,
poaltLve, say 1-, J,
1
Itatl
r 0' say
PN have eomeeleuente
fhen (v111) lnplles
- o J " - . . . - b k a- . a r - o , (1*).
Ihus,wlth
the aesunptlon
of
(c)
and (B)'
59
(rn) lnnllee the orlglnal
suppoeltlon v-n . i* 1" inpoesl-ble, eo
the theorem le proved. Glven (c) a n d ( B ) ,
Corollary.
(Y ) tnpllee N -
-l'I u M - '
for
H : tl, eo (G) inplles
all
The argurent
for
thle
-M
'
thls
''M
for
all
M, and (f)
lnplles
ls glven ln the dlscueslon
before
; = I
.
the
theorem.
18.
Conpound growth
and lnteregt
Coneider an econouy ln eucceesive perloda the actlvlty
ln each perlod
of sone n goods, and lt (1)
lnput-output
(2\
the output
1s descrlbed
of productlon,
by an lnput
where
and an output
is aeguned that poselbllltles
of one perlods
are the same ln all ls
the resource
for
perlode the lnput
of
the next (3)
there 18 free dleposal of both ourpur and lnput.
BV (1), poseLbllltles (x, y),
some relatlon
R c 0n t 0n gives the lnput-output
acrosa any perlod,
6(', y')
and by (2) for
to be succeeslve lt
ls requtred that y i
the condltlon
for any (x1, yl),
of actlvLtles
through N auccesslve perlods
(4)
xrRyr i
The resultant
x2Ry2:
...\RyN
...,
(5,
*t.
Thue
yn) to be a poselble chain ia
xrRyr I xzRyz i
of such a chain 1e the input-output
acroas a apan of N perlods.
lnput-outputg
These reeultants
(xt,
...
: **nr"
yN) lt
of poesible
determines
chalns of
70
length N describe the lnput-output It
derlves
as the Nth.orpound
perlod,
deflned
rdcursively
perlods. unlt
relatlon
Possiblllty
\
across N R across a
of the relstlon
by Rt = R wlth N-1
(5)
*\y
= (vx', y')xR^'^ Y'1x'RY (3) le
The assumptlon of free-dlsposal x'
(6) Wlth this,
: 1 xRY : Y'
(5) ls equlvalent
(7)
to = (vz)xn*-t
*\v
whlch establlshes
simply
\
for
property
the slnple
for
Free-disposal
x'
Also lf
'r xRNy I yt
that
follows
lf
R is
Maxtnuro Sroltth by repetltion alngle
-
N
d*:6",
planned
for
can be no better,
plan coverlng
6 deter:nlned fron -
regular
the entlre
*tRNyt
the same
.
or convex, so 1s RN. lmply the same for
l-e homogeneous and has bounded output rt
lnplles
RN ,
R does not generally
for
R obvlouely
relatlon
R le homogeneousr addltlve'
continulty
'N-IRY
z*-t)xRztR "'
the compound relation
(e)
znY '
as the Nan Potrer RN of R, glven by
xRNy= (v21,...,
(8)
x'RY' .
then lt
crasslcal
perlod.
R, and correspondlngly
ls not
RN, but
if
R
does by theoren 5.1.
homogeneous then so ls RN.
one perlod and night
It
and extended
over N
conpare unfavourably Thus wlth [N
with
a
the growth factor
from RN, ln any case
p r o v l d e d R l s h o r o o g e n e o u s ,a n d t h e r e c a n b e e n q u i r y a b o u t
the poesibllfty
p" , !N.
taken as the accounttng
Wlth a succession period,
ae well
of N baslc
perlods
as the production
being
perlodr
the
7l
interest fron
i*
factor
derives
the dual R* of R,
fron
the d,ral RN* of RN, Just as i
Wlth R regular
rh dual of Ehe N-" power ls
classical
derives
homogeneous, the
rh the N-" power of rhe dual,
RN* = R*N , by'theoren
11.3.
grohrth factor lnterest
Ttrus wlth
S = R* as the dual of R, wlth
o-, SN 1" ldentical
factor
ir,
wlth
the dual of RN.
being the reclprocal
N*
R.' , becones ldentlcal
naximum
The N-perlod
of the growth factor
\.rlth the reclprocal
of
of the growth factor
o"
N
of SA.
But, from hourogenelty, 6u i
6N , and hence, fron
the reclprocals,
- - N v N : v Theoren 18. I If a unlt
R is a regular
perlod
wlth
are the grovth
classlcal
honogeneous productlon
growth and intereet
and lnterest
p-, i
factore
over N perlods
factors
relatlon
and if
6",
for
i,
then
i * 5 i N : 0 " : o * . Thls ls
shown ln che foregoing
theorem 13.3, corollary Thls wlll
dlscueelon,
together
(1), which ahowethet;:
now be applled
to a productlon
Ne,mann fotm R = AB where A, B are deternined
wlth
o . the von
wlth
relatlon
from matrlces
a, b b,
x A t = x : a t , t B x : b t > x , and for whlch the conditions and the last followlng
sectlon,
applles
(o),
(B) whlch appear ln Sectlon
are the regularlty
ln any relatlon
For anv relatlon
conditione.
Flrat,
A, B and ln particular
R deflne
u(R)-Bup[u:xRxp,xz0]
8, the
to these.
12
Thue, wlth
R a productiotr
f.
relatlon,
and S = R*,
p ( R ) 'd = u ( S ) ,i = d - l
Theoren 18.2 If
A le hooogeneous and B regular
then
t [u : xA3xp' x ) 0, U > 0] For lf
[u : tBAtu, t > 0'u > 0]
B ls regular, t B x , x 2 Q : t ) 0 ,
wtth u > 0, and by horoogenelty of A,
so that,
xAtBxu, x ) 0 :
tBxuAtu,
t 2 0,
and hence (vt)
(vx)xABxu, x 2 0'+
tBAtu, t 2 0,
aa requlred. (1).
Corollary
A ls honogeneous and B regular
If
then
u(AB) : u(BA) (il).
Corollary
A, B are honogeneous and B regular
If
u((AB)N) i
then
u((na)N)
For (AB)N - CB,
(nl;N = ss
where c - l(sl)N-l
s
A, B are hooogeneous then so la C.
Also lf Corollary
(111).
E
n, I are homogeneoue and regular
then
u((AB)N) - u((BA)N). Now wtth
the von Neunann relatlon
R - AB detetmlned
from matrlces
I-t
a, b the dual is S = A*B* lthere pSq = pa > qb, and chls shows thac the lnterest treated (c),
factor
ln the prevlous section.
i*
colncldes
wlth
the in
A1so, subJect to the conditlons
(B) so that A, B are regular. -
N
N
DN=u(R^')= u((BA)") But BA is
for whlch
the relatlon
sBAt=sb>ta, and thls i-N
shorvsthat,
treated
subJect to (q) and (g),6*
ln rhe laet
aectlon.
colncldes rrlth the
Theorem 17.2 and lts
corollary
thus glve the following. Theoren 18.3. For the von Neumann productlon matrlces a
and b sublect
the absense of gap-cvcles
to the regularltv lmp1les that
/v perlods is Just the Nth power of that and slurilarly
wlth
R deternlned
relation
the rninlsrun lnterest
condltlons
(o) and (B),
the naxlnum grosth factor factor.
from
factor
acroae a elngle
acroas perlod,
74
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