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Annals of Mathematics Studies Number 52
ADVANCES IN GAME THEORY R. J .
AUMANN
L. D. BERKOVITZ M. W.
H.
DAVIS
F L E M IN G
A. R. GALM ARIN O O. GROSS J.
C. H ARSAN YI M. J.
HEBERT
R. ISBELL
G. JE N T Z S C H S. M .
J-
M Y C IE L S K I
E. D. NERING H.
NIKAIDO
G. OWEN B.
PELEG
H. RADSTROM R. A. RESTREPO
J^C.
L. ROSENFELD R Y L L -N A R D Z E W S K I
R. SELTEN L. S. S H A P L E Y
JO H N SO N
M.
MASCHLER
R.
E. STEARNS
K.
M IYASAW A
L.
E. ZACHRISSON
EDITED BY
M. Dresher, L. S. Shapley, A . W . Tucker
PRINCETON, NEW JERSEY PRINCETON UNIVERSITY PRESS * 964
Copyright © 1964, by Princeton University Press All Rights Reserved L. C. Card 63-9985 ISBN 0-691-07902-1 Second Printing, 1971
Printed in the United States of America
PREFACE This Study carries on the tradition of the four volumes entitled Contributions to the Theory of Games;* it is similar in format, but has a different reason for existence.
The field of game theory is now well
established and widely diffused through the mathematical world, thanks in part to the success of the earlier volumes; papers on game theory regularly appear in many scientific journals.
But with no single, specialized journal
as focal point, there remains a serious problem of communication within the field.
It is often difficult,
newcomers,
for isolated workers and especially for
to get abreast of developments,
find out where the significant
new problems lie, and avoid needless duplications of effort. Accordingly,
this Study was conceived as a one-volume cross section
of current activity in the theory of games.
Contributions were invited from
a widely distributed and, it is hoped, representative group of investigators, and twenty-nine papers were finally accepted.
Most of these might otherwise
have appeared in one or another of the regular mathematics, economics, or operations research journals.
It is hoped that the authors will agree that
publication of their work in the present volume is a step toward improving the accessibility of the expanding frontiers of the theory. The scope of this collection was arbitrarily drawn to exclude theoretical essays of primarily nonmathematica1 content, as well as mathema tical applications of primarily nontheoretical interest. expository articles were solicited.
Also, no purely
Within these limits, however,
the
editors welcomed variety, not only in subject matter, but also in the level of the mathematical techniques invoked and in the level of abstractness or particularity in the approach.
As the browsing reader will quickly discover,
the contents of this book are far from homogeneous either in style, Annals of Mathematics Studies 24 (1950), v
in
28 (1953), 39 (1957), 40 (1959).
PREFACE prerequisites, or in pertinence to any one area of interest. As for subject matter, the editors can point to a good balance, achieved without premeditation, on many different accounts:
two-person vs.
n-person games; finite vs. infinite games; extensive vs. normal form; sidepayment vs. no-side-payment games; cooperative vs. noncooperative games; existing theory vs. new departures; etc.
This evidence of activity on all
fronts speaks well for the vitality of the field as a whole, as does the large international authorship of this volume. The contributions are arranged not by order of receipt, but by subject.
It no longer seems appropriate, however, to organize the book into
sections, as in earlier volumes, nor to attempt in the Preface to survey the contents from a unified viewpoint.
Nevertheless, a brief description of the
subjects that are covered will be given here to provide a bird's-eye view of the book as a whole and to supplement the bare titles in the Table of Contents. The first thirteen papers deal with two-person games.
In the first,
SHAPLEY explores several topics growing out of the theory of matrix games, particularly their ordinal properties.
Papers
2 and 3, by RESTREPO
and
JOHNSON, concern the solving of particular two-person games; the first is an abstract poker model, the second is a mathematical form of "hide and seek". Papers 4 and 5, by GROSS and NIKAIDO, apply the minimax theorem to point-set topology and mathematical economics, respectively.
In Paper 6, ROSENFELD
investigates the repeated play of a game matrix in which the values of some of the entries are not known to the players in advance.
In Papers 7 and 8,
DAVIS and MYCIELSKI carry on the study of infinite games of perfect informa tion begun by Gale and Stewart in Study 28; the second paper makes an application of that discrete-time model to what could be called positional games with continuous time.
This type of game is treated systematically in
Paper 9 by RYLL-NARDZEWSKI, using general topological and set theoretical notions, and in Papers 10, 11, and 12 by BERKOVITZ and FLEMING, using techniques from the calculus of variations.
Finally, ZACHRISSON,
in Paper 13,
considers games in which the strategies of the two players generate a Markov process; again information is essentially perfect and time may be a continuous parameter.
vi
PREFACE The last sixteen papers are in the field of n-person games. Paper 14, ISBELL determines the existence, particular kind of n-person simple game.
for various values of
n, of a
Papers 15 and 16, by SHAPLEY and
OWEN, study the solutions of a class of games, mostly simple, certain compound structure.
In
that exhibit a
The next two papers, by GALMARINO and HEBERT,
study two aspects of the solutions of all four-person constant-sum games. STEARNS,
in Paper 19, obtains all solutions of all three-person games in the
no-side-payment theory.
In Paper 20, JENTZSCH considers the general theory
of cooperative n-person games, with and without side payments.
Papers 21,
22, and 23, by AUMANN and MASCHLER, MASCHLER, and PELEG, develop and apply a new solution concept of "bargaining set" for cooperative games in characteristic-function form.
RADSTROM,
in Paper 24, introduces a solution concept
leading to certain "basic" imputations, each being associated with a hierarchical coalition structure of a certain kind.
NERING,
in Paper 25,
advances still another solution concept for characteristic function games, based on the merging of players into successively larger coalitions.
A
common feature of these new solution concepts is that they all generalize the celebrated three-point classical solution to the zero-sum three-person game. MIYASAWA,
in Paper 26, formulates a bargaining model for general cooperative
games in normal form that leads to a one-point solution, or "value".
SELTEN,
in Paper 27, axiomatizes the valuation of n-person games in the classical theory, basing his considerations primarily on the extensive form.
AUMANN,
in Paper 28, considers infinite games in extensive form, in which continua of choices at each move as well as plays of infinite length are permitted; his results on behavior strategies would apply most directly to the noncooperative theory.
Finally, HARSANYI,
in the concluding paper, undertakes to analyze
and refine the equilibrium-point concept with the goal of providing a unique solution to noncooperative games. *
*
*
The editing of this volume was done primarily at The RAND Corporation, which provided the services of two of the editors, as well as secretarial help.
The Office of Naval Research supported the work of the third editor
through its Logistics project at Princeton University.
Thanks are also due
that project for providing the English translation of Paper 18, and to The vii
PREFACE RAND Corporation for making available its translation of Paper 20.
The
burden assumed by several other authors in supplying texts in English, not their native language, should not be overlooked. referees
A host of anonymous
(including a majority of the contributors as well as several others)
gave willing assistance; many of them performed beyond the call of duty.
The
typing of the master copy has been the painstaking and efficient work of Mrs. Margaret Wray.
Finally, the Princeton University Press, through its
Science Editor Jay Wilson, has been constantly interested and helpful throughout the preparation of this volume.
To all those who have given their
assistance, the editors offer their sincere thanks.
NOTE A few of the papers in this Study were among the 39 papers presented at the Princeton University Conference on Recent Advances in Game Theory, October 4-6, 1961, directed by Oskar M o r g e n s t e m and A. W. Tucker.
Proceed
ings of this Conference were prepared by Michael Maschler for the Econometric Research Program, Department of Economics, Princeton University, and were privately printed for members of The Princeton University Conference.
M. Dresher L. S. Shapley A. W. Tucker
December 1963
viii
CONTENTS
V
Preface Paper 1.
Some Topics in Two-Person Games By L. S. Shapley
1
2.
Games With a Random Move By Rodrigo A. Restrepo
29
3.
A Search Game By Selmer M. Johnson
39
4.
The Rendezvous Value of a Metric Space By 0. Gross
49
5-
Generalized Gross Substitutability and Extremization by Hukukane Nikaido
55
6.
Adaptive Competitive Decision By Jack L. Rosenfeld
69
7.
Infinite Games of Perfect Information By Morton Davis
85
8.
Continuous Games of Perfect Information By Jan Mycielski
103
9.
A Theory of Pursuit and Evasion By C. Ryll-Nardzewski
113
10.
A Variational Approach to Differential Games By Leonard D. Berkovitz
127
11.
A Differential Game Without Pure Strategy Solutions on an Open Set By Leonard D. Berkovitz
175
12.
The Convergence Problem for Differential Games, II By Wendell H. Fleming
195
13.
Markov Games By Lars Erik Zachrisson
211
14.
Homogeneous Games, By J. R. Isbell
255
15.
Solutions of Compound Simple Games By L. S. Shapley
267
16.
The Tensor Composition of Nonnegative Games By Guillermo Owen
307
III
ix
CONTENTS Paper 17.
18.
On the Cardinality of Solutions of Four-Person ConstantSum Games By Alberto Raul Galmarino
327
The Doubly Discriminatory Solutions of the Four-Person Constant-Sum Game By Michael H. Hebert
345
19.
Three-Person Cooperative Games Without Side Payments By R. E. Stearns
377
20 .
Some Thoughts on the Theory of Cooperative Games By Gerd Jentzsch
407
The Bargaining Set for Cooperative Games By Robert J. Aumann and Michael Maschler
443
Stable Payoff Configurations for Quota Games By Michael Maschler
477
23.
On the Bargaining Set By Bezalel Peleg
501
24.
A Property of Stability Possessed by Certain Imputations By Hans Radstrom
513
25.
Coalition Bargaining in n-Person Games By Evar D. Nering
531
26.
The n-Person Bargaining Game By Koichi Miyasawa
547
27.
Valuation of n-Person Games By Reinhard Selten
577
28.
Mixed and Behavior Strategies in Infinite Extensive Games By Robert J. Aumann
627
29.
A General Solution for Finite Noncooperative Games Based on Risk-Dominance By John C. Harsanyi
651
21
.
22
.
9fHn
of m-Quota Games
x
ADVANCES IN GAME THEORY
SOME TOPICS IN TWO-PERSON GAMES L- S. Shapley
INTRODUCTION
This note reports on half-a-dozen loosely related excursions into the theory of finite, two-person games, both zero-sum and non-zero-sum.
The
connecting thread is a general predilection for results that do not depend upon the full linear structure of the real numbers.
Thus, most of our theor
ems and examples are invariant under order-preserving transformations applied to the payoff spaces, while a few (in § 1) are invariant under the group of transformations that commute with multiplication by
— 1.
We should make it clear that we are not interested in "ordinal" utility, as such, but rather the ordinal properties of "cardinal" utility. The former would require a conceptual reorientation which we do not wish to undertake here.
Nevertheless, the ordinalist may find useful ideas in this
paper. Rather than summarize the whole paper here, we shall merely take a sample; for a more synoptic view the reader is invited to scan the section headings.
Consider first the matrix game shown in the margin.
The solution is easily found as game is symmetric in the players.
soon as we recognize that the Indeed,
player's it^1 strategy into the other's
if we map
0 - 1 0
each
i+lst (mod 4), we
merely reverse the signs of the
payoffs.
and that there is a solution of
the form
1 2 - 1
It follows that thevalue
1-2
2 - 1 0 1 1
-
2-1
is
(a,b,a,b), (b,a,b,a). (See §
0
0 1.)
Next, consider the class of matrix games in which the payoffs are ordered like those in the matrix at left
(next page).
In all these games,
player I's third strategy is never playable, although it is not dominated in the usual sense.
To verify this, observe that if the value of the 2-by-2 1
2
SHAPLEY
10
0
8
subgame in the upper left c o m e r is greater than "3" the third
1
9
7
row is dominated by a linear combination of the first two rows,
2
3
6
while if it is less than "7" the third column can be dropped,
3
4
5
and then the third row.
(See § 3.)
Finally, consider the non-zero-sum game with outcome matrix as shown at right.
Player I rates the outcomes
rates them
B > A > C.
A > B > C; player II
If we apply the algorithm of "fictitious
play" to this game, a strange thing happens.
Rather than con
A
C
B
B
A
C
C
B
A
verging to the unique equilibrium point (at which all probabilities are equal), the sequence of mixed-strategy pairs generated by the algorithm oscillates around it, keeping a finite distance away.
(See § 5.)
The five main sections of this paper are essentially independent, both logically and topically.
Our reason for combining them into a single
paper is the hope that they will appeal to a single audience.
Much of this
work has already appeared in short RAND Memoranda [15], and some of it has been cited in the published literature [5],
[11].
In reworking this material,
however, we have added many new results.
§ 1.
1.1.
SYMMETRIC GAMES
Discussion It is easy to see that a two-person zero-sum game can be symmetric
in the players without having a skew-symmetric payoff matrix.
"Matching
Pennies" is a simple example; another is shown at the right; and another is given in the Introduction.
The point is, of course,
that an automorphism of the game that permutes the players can simultaneously shuffle the labels of the pure strategies.
1 1 - 1 -1
0 -1
- 1 1 1
It would be inter
esting to know something about the abstract structure of such automorphisms.* As a first step, we shall show that the matrix of a symmetric game can be decomposed into an array of square blocks in such a way that (a) block has constant diagonals
(in one direction),
skew-symmetric in a certain sense, and (c)
(b)
each
the array as a whole is
the size of each block is a power
The narrow "skew-symmetric" definition is most often seen in the liter ature (e.g., [19], [10], [7]). But Nash uses the more general form in [13]; see also [19], p. 166.
TWO-PERSON GAMES 3
2
of 2.
1 -1
1
given above.
1 1 3
-1
1
1
2
-1 -1
0
This is illustrated at left for the 3-by-3 example
The "power of 2" property,
(c), is quite interesting.
It
tells us, for example, that the 6-by-6 game illustrated below,
which is obviously symmetric and has constant diagonals, can nevertheless be decomposed into smaller blocks.
The 4-by-4 and 8-by-8 analogues of this
matrix, on the other hand, do not decompose.
1
1.2.
2
3
1
1
2
-1
3
-2-1
4
-3-2-1
4
5
6
2
2 3 -3 -2 -1
1
1 23 - 3 - 2
4
1
5
3
2 -2 -2
6
4
1
3 -1
-3
1
2 -1
3
1 -3
2 -2
3 -1
2
3-3
2
1
2
3
5
-3
1 -2
-1
3
5
3
-3 -2 -1 1
2
3
6
2
3 -3 -2 -1
1
6
1 -3
3 -1
2 -1
2 -2
1 -3 -3
3
1 -2
2
The Main Theorem Let
and let
A, B,
P, Q, R,
...
...
denote n-by-n game matrices
(n
fixed throughout),
denote permutation matrices of the same size.
Primes
will denote transposition, which is equivalent to inversion for permutation matrices.
We define the following matrix properties:
equivalence: A
=
B A = PBQ'
symmetry:
A
e
2 A == —A 1 .
conjugates:
P
Certain subclasses of
Q
P = RQR'
These subclasses exhaust
If
P, Q.
for some R.
2, will also be of interest:
A e 2 (P,Q) B = — P B 1Q 1
LEMMA 1.
for some
for some
2 , but are not disjoint.
PQ w RS
then
B = A.
Indeed, we have
2(P,Q) = 2(R,S).
4
SHAPLEY PROOF.
that since
Given
B = — RB'S'.
PQ = TRSTr
and
A = — PA'Q1, we require
As it happens,, B = T'AP'TR
B = A
serves the purpose.
such
Indeed,
P r = QTS'R'T', we have
B = T '(— PA'Q') (QTS1R'T')TR = -T'PA'TS' = - (T1A P 1T) 'S 1 = -RB 'S'.
Note that where
I
Z(P,Q)
depends only on
PQ.
If we define
2(P) = 2(P,I),
is the identity, then Lemma 1 may be restated:
LEMMA l 1.
If
P ~ Q
then
Z(P) = 2 (Q).
It can be shown that the converse is valid.
Since two permutations
are conjugate if and only if their cyclic factors have matching periods, there is thus a one-to-one correspondence between the classes partitions of
n.
LEMMA 2.
PROOF. all k. fore
But
If
Q
Suppose
is an odd power of
A = — PA' .
P
A = — P(— P A 1)' = P A P 1; hence
and the
2(Q) 3 2 (P)-
A e Z(P
21,4-1
)
A = PkAP'k = - Pk+1A ' P ,k.
for There
A € Z(Pk+1, Pk ) = Z(p2k+1).
THEOREM 1.1.
Every symmetric game
A e 2
to a game
satisfying
for some permutation
PROOF. k
c2 , with
A e 2(PC ).
1.3.
then
We must show that
B
B = — RB'
R, the order of which is a power of
form
2(P)
This stronger result is not used in what follows.
Thus
Let c
A e 2(P). odd.
Pc
2.
The order of
Then the order of
will serve as the
R
is equivalent
P P
c
can be represented in the will be
k 2 .
of the theorem.
By Lemma 2,
Q.E.D.
Block Decomposition The decomposition into blocks can now be described.
By proper choice
TWO-PERSON GAMES ofB, we can give
5
R the form:
R = (1 2 3 A^)(A j+l . . . X j+7v2) ••• (••• n),
where of
the periods
A^-by-A^
A^ are powers of
blocks
ant*
by) thestructure set forth
2.
B
the equation
now breaks up into B = — RB'
in the following theorem.
a square array
implies (and The proof
is
implied
is straight
forward.
THEOREM 1.2.
A = min(A
, A ). N l~i v'
Let
has constant diagonals, . ..,
exist such that for
b^j
(If
A^
sub-blocks of size block
B
B
|jv
ij
in that block,*
if i — j = h (mod A ) .
=
A^, then
The block
in the sense that numbers
B
breaks
A .)
In
up into identical square
thesymmetrically located
the same numbers appear; we have
by
= -P A_ h+1
if
i - j = h (mod A ) .
In particular, along the main diagonal of the array (\d = v ) ,
we have
COROLLARY 1. exist only for
COROLLARY 2.
for
h = 1, . . ., A.
Indecomposable symmetric n
a power of
n-by-n games
2.
Every symmetric game of odd size has a
zero in its payoff matrix.
1.4.
Solutions To solve a symmetric game we may (a)
TF--------------We write ij
for the ordered pair
replace the
(i, j).
B^v
by their
6
SHAPLEY
average values,
(b)
solve the resulting skew-symmetric matrix,* and (c)
distribute the mixed-strategy probabilities for each block equally among its constituent pure strategies.**
Not every solution of the
original can be obtained in this way, however. at the right, for example,
(0, 2/3, 1/3, 0)
In the game
-1
-2
-2
2
2
4 -4 -4
4
Symmetric Nonzero-sum Games There is a direct extension to nonzero-sum games.
matrix pairs A^ = PB-^Q1 and
1
2 -2
is a basic
(extreme) optimal strategy of each player.
1.5.
2 -2
1 -1
(A^, A 2) and
( A ^ A^)
and
(B^, B 2)
A 2 = PI^Q' •
equivalent if, for some
Let us call
are equivalent.
Let us call the
(A^, A
P, Q, both
symmetric if
(A^,
Then the following counterpart to Theorem 1.1
can be established by essentially the same proof:
THEOREM 1.3.
Every symmetric nonzero-sum games (A-^, A
is equivalent to a game for some permutation
of the form
(B^, B 2)
R of order a power of
=(RB^ RB^)
2.
The description of the block decomposition remains much as before, though the "main diagonal" loses some of its special significance.
Corollary
1 remains valid, but not Corollary 2.
§ 2.
2.1.
SOME THEOREMS ABOUT SADDLEPOINTS
A Condition for the Existence of a Saddlepoint
THEOREM 2.1.
If
A
is
the matrix of a zero-sum two-
person game, and if every 2-by-2 submatrix of saddlepoint, then
PROOF.
Let
A
A
has a
has a saddlepoint.
val[A] = v.
Let
j
be the index of a column having
the minimum number, n , of entries greater than
v.
Suppose
tt
> 0; then, for
See Kaplansky [10] and Gale, Kuhn, and Tucker [7]. **
See for example, Gale, Kuhn, and Tucker [8 ], application (e).
TWO-PERSON GAMES some
i
have
a^.. , < v
7r
we have
a^
> v.
for some
entries greater than
maining entries
> v
a i'j' ^ v — a i'j’
has no saddlepoint,
Since the value of the game is only j '.
But the column indexed by
2.2.
jf
v, we must
has at least
v, too many to be paired off against the
of the other column.
Thus., for some
i'
7T— 1
re
we have
Since the 2-by-2 submatrix: j
j'
i
>V
i'
0
v.
was incorrect.
Hence there is a
Similarly there is a row with no
Q.E.D.
Detached Rows and Columns The hypothesis of Theorem 2.1 actually imposes a very special struc-
ture on the matrix
A.
Let us say that the p
max a . < max
j Similarly,
the
th
row of
A
is detached if
min a ...
PJ “ it*
1J
j
column is detached if
min a . > min i lq J
max a ... i 1J
Detachment obviously implies domination.
For 2-by-2 matrices,
the existence
of a detached row or column is equivalent to the existence of a saddlepoint.
THEOREM 2.2.
If every 2-by-2 submatrix of
saddlepoint, then
PROOF. saddlepoints.
A
By Theorem 2.1, both
val[A'].
If
A
and
Hence there is a column of
val[A], as well as a column of
A
has a
has a detached row or column.
A
A
(row of
A'
(itstranspose)
have
with noentries greater
than
A 1) with no entries less than
val[A] < val[A'], then these columns are distinct, and the
latter is a detached column.
Similarly,
if
val[A] > val[A'], there is a
8
SHAPLEY
detached row.
If
val[A] = val[A'] = v, then there is either a detached row
or column, or a saddlepoint case, a^j = a ^
= v, all
obtained by deleting row either is
p
> v
2.3.
or or
q
pq
common to both
A
and
A 1.
In the latter
i,j, and we can use the fact that the submatrix p
and column
q
has a saddlepoint to show that
is detached, depending on whether the value of the submatrix
< v.
Q.E.D.
A Generalization Theorem 2.1 can be generalized, after a fashion.
Let us say that a
matrix is "in general position" if no two collinear entries are equal.
THEOREM 2.3.
Let
position,
and let
submatrix
of A
A
be an m-by-n matrix in general
2 < r < m, 2 < s < n. has a saddlepoint, then
If every r-by-s A
has a saddle-
po int.
PROOF.
It suffices to prove the case where
r = m > 2
s = n— 1 > 2; the rest will follow by induction and symmetry.
Let
and A4
denote
___ A
with the q
of
A4
jq's
column deleted.
(which is unique, since are distinct, for
Let A
i j be the location of the saddlepoint q q is in general position). If all of the
q = 1, ..., n, then every
column of
A
will contain
one of the points
i j. Since each a. . is a column maximum, one of them QQ 1 1 44 qJ q will be the maximum of the whole matrix. On the other hand, it must also be the (strict) minimum of its row in This impossibility implies that the q f
t-
A.
Q.E.D.
A 4 , which contains at least two entries. Jq's
Then it is apparent that the point
are nQt a H
distinct.
iqjq = itj t
At right we illustrate what can happen if two collinear entries are equal.
Every 3-by-2 submatrix has a saddlepoint,
but not the full matrix.
Definitions.
= j
1 0 - 1 -2
0
2
2 - 1 3
§ 3.
3.1.
Let
is a saddlepoint of
ORDER MATRICES
The Saddle
By a line of a matrix we shall mean either a row or a column.
Two
TWO-PERSON GAMES
9
numerical matrices of the same size will be called order equivalent if the elements of corresponding lines are ordered alike.
An order matrix,
an equivalence class of order-equivalent numerical matrices.
ft, is
Abstractly,
it
may be regarded as a partial ordering pairs
< on the set I (ft) of all index Ct ij, with the property that collinear points are always comparable,
while noncollinear points are never comparable, except as a result of trans itivity. If
K c
I (ft)
is a set of index pairs, we shall
set of first members, ^ In other words, columns, and
for the set of
second members, and
is the smallest set of rows,
K
write K-^ K
for the
for
K-^ x
the smallest set of
the smallest submatrix, that covers
K.
If
K = K
then
K
is rectangular. A generalized saddle point gular
set
K c= I (ft)
(GSP) of an order matrix
such that (1)for each
i ^ K-^
ft is a rectan
there is a
pe
pj > ij for all j e K 9, and (2) for each j ^ K 9 there is a q e K 9 Ct __ z z with iq < ij for all i e K-. .* (Note the strict inequalities.) A GSP that Ct contains no other GSP is called a saddle. with
THEOREM 3.1.
Every order matrix has a unique saddle.
The proof consists in showing that the intersection of two GSP's is a GSP.
Let
K
L
and
matrix
K
and
belonging to
thereis a
L
be two GSPs of
K 0 L f , since
Then certainly
p
in
ft.**It will suffice to
K-^ ft
with
find a
p 1 e K-^ with that
we can
find a
thenp ,M e K-j^
p" e L-^
pj > ij
property, since with
p"j > p 1j
showthat for all K
j e ^
is a GSP.
for all
n L-^
that majorizes row
The saddle of
ft
sequenceterminates. i
on
will be denoted
for each H L2 * If
p'
j e K2 H
can be found bearing the same relation to
strict inequalities ensure that the row in
ft.
must both carry the optimal mixed strategies ofany numerical
L2 . by S(ft).
p", etc.
i ^ K-^ But we can £ L-^, then
If
p" £ K^, The
That is, there
is a
Q.E.D. It contains
everything
Compare [5], pp. 41-42. ** Bass [1] found a way to prove to optimal strategies.
K fl L =f (|)
directly, without reference
10
SHAPLEY
relevant to the solutions of the numerical games particular,
A
belonging to
ft.
In
it contains Bohnenblust1s "essential" submatrix* and the Shapley-
Snow "kernels."** We may define a weak GSP by using nonstrict inequalities
>, ,
where
y '(uu)
is like
y(uu)
except for
y^(uu) = 0
and
y^ (uu) = yg (^) + y^C^)-
Hence, by (3.2)
val[A(uu)] > val[A^] + P||y* — y 1(uo)|| — 4a^/uu,
andy '(uu) y (uj) But
converges toy*,
- y*> 0.
A(uu) e Cfc
Thus both
by Lemma 4. r
and
for all positive
LEMMA 6 .
If
®
uu.
Since
yq(w) "* 0* we
s are active in Hence
is obtained from
A(uu)
rs e C(Ct).
have
for large
uu.
Q.E.D.
Ct by the deletion (as
in Lemma 5) of a strictly majorized row or a strictly minorized column, then
PROOF.
C((B) £ C(Ct).
A strictly dominated strategy can never be active.
THEOREM 3-4.
If
Ct
is in general position, then
R# (Ct) c C(O).
PROOF.
The theorem follows directly from Lemma 5 (and its "row"
counterpart), Lemma 6 , and the definition of restricted residual.
3.7.
The Antisaddle We close this part with a simple result concerning antisaddlepoints,
i.e., saddlepoints of the negative matrix.
THEOREM 3.5.
A strict antisaddlepoint of
be in the center, unless
Ct
is 1-by-l.
Ct
cannot
TWO-PERSON GAMES PROOF.
Suppose
pq e C(A), and let
A
S(- v
and
xM(v)y < v.
y
solutions v < v.
Let
x
be optimal in M(v)for player
Subtracting, we obtain
v - v < x (M(v) - M (v ) )y = xQy0 (v - v) .
Hence
X q = Yg = I j and
x
and
y
are pure.
Thus, for all
i f 0, j f 0,
a0j > v > v > a.0 .
This contradicts
(4.1).
Existence. ing.
The function
F(a) = val[M(a)]
is monotonic nondecreas
Hence, by (4.2), we have
F(min aQ .) < F ( v J ; j+o °J 1 in other words
v^ —
is continuous; hence
COROLLARY.
F(v^) < 0.
Similarly, v ^ — F C ^ ) > 0.But
it has a zero in
a
— F(a)
[v^, ^ 2 ]’ ’ Q.E.D.
In the determinate case,
v is equal to
the true v alue.
We note that if (4.1) is not satisfied, then all values in the interval
[max a^Q, min a Q ^ ] From the fact that
creasing functions,
are solutions of (4.4), and no others. F(a)
and
a — F(a)
it follows that the sequence
are both monotonic nonde b, F(b), F(F(b)),
arbitrary) converges monotonically to a solution of (4.4). ful in making sharper numerical estimates; e.g., we have
...
(b
This can be use F(v^) < v < F(v2)j
24
SHAPLEY
etc. In the first indeterminate game of § 4.2 we have In the second example we also have
v = 0, by symmetry.
v = 0; thus, the first player's advantage
in this game, such as it is, vanishes if time is made discrete.
This feature,
also present in the order-equivalent variants, shows that strict inequality need not hold in Theorem 4.5 for indeterminate games.
§ 5.
5.1.
FICTITIOUS PLAY IN NON-ZERO-SUM GAMES
Discussion The method of fictitious play (FP) resembles a multistage learning
process.
At each stage, it is assumed that the players choose a strategy
that would yield the optimum result if employed against all past choices of their opponents.
Various conventions can be adopted with regard to the first
move, indifferent alternatives, simultaneous vs. alternating moves, and weighting of past choices.
The method can meaningfully be applied to any
finite game, and to many infinite games as well.
(See [3],
[4],
[5] pp. 82-
85, and [14].) It was once conjectured that the mixed strategies defined by the accumulated choices of the players would always converge to the equilibrium point of the game, or, in the event of nonuniqueness, compatible equilibrium points.
to a set of mutually
This is the natural generalization of
Robinson's theorem [14] for the zero-sum two-person case; it was recently verified by Miyasawa [12] for the special case of two players with two pure strategies apiece. The trouble begins, as we shall see, as tegy for
each player.
soon as we add a third stra
It appears, intuitively, that this size is
to produce enough variety;
if
FP
necessary
is to fail, the game must contain elements
of both coordination and competition.
Our counterexamples include a whole
class of order-equivalent games, and thus do not depend on numerical quirks in the payoff matrices; nor are they sensitive to the minor technicalities of the
FP
algorithm.
It is clear that games with more players, or with more
strategies per player, can exhibit the same kind
of misbehavior.
TWO-PERSON GAMES 5.2.
25
A Class of Nonconvergent Examples We shall elaborate slightly on the game described in the Introduc
tion, to eliminate any question of "degeneracy.” shown at right. ai ^
We assume that
^ ^i* ^or
a^ > b^ > c^
i B 1) 2, 3.
game is not constant-sum.
The payoff matrices are
and
It follows that the
It is easily shown that
the equilibrium point must be completely mixed (all II strategies active), and hence unique. For simplicity, we shall assume that the
FP
ultaneously, and that the first choice pair is 11. of 1
11
in the
again,
FP
sequence.
choices are made sim
Consider any occurrence
The next choice of player I will certainly be
since that strategy will have become more desirable.
either stay with
1, or shift to
3, since
3.
Eventually,
Thus, after each run of
11
in fact, he must shift to we will find a run of
By a similar argument, this will be followed by a run of of
32, 22, 21, 11,
...,
Player II will
33, and then runs
in a never-ending cycle.
Suppose that a run of
11
is just about to begin.
Let
the current "accumulated-choices" vector for player I (thus, of times he has chosen row H
13.
i), and let
Y
X
represent
is the number
be the same for player II.
Let
denote the current "comparative-payoffs" vector for player I (thus, H-^ =
Yia i + '^■ H-j^ — H p
and we have
> Hp
But
< Hp
26
SHAPLEY
al ~ C1 r 13 ^ a 3 - b 3 r ll*
Let
r 33
be the length of the
33
run that follows.
By analogous reasoning
we have
al ” Y1
r33 ^ a3 - P3 r13"
Repeating the argument four times more, we obtain / 3 (5-1)
rh
where
r^
(5.1)
is greater than
- Viix /c,
(■)
(04 , 04 , 02; e5, 03, e)/ce, etc.,
is a normalizing constant.
(O)
The unique equilibrium point is
(1, 1, 1; 1, 1, 1 )/3•
Figure 2
BIBLIOGRAPHY
[1]
BASS, H., Order Matrices, Junior Paper, Princeton University,
[2]
BOHNENBLUST, H. F., KARLIN, S. and SHAPLEY, L. S., "Solutions of discrete, two-person games," Annals of Mathematics Study No. 24 (Princeton, 1950), pp. 51-72.
[3]
BROWN, G. W . , "Iterative solution of games by fictitious play," Activity Analysis of Production and Allocation, John Wiley and Sons, 1951, pp. 374-376.
[4]
DANSKIN, J. M . , "Fictitious play for continuous games," Naval Research Logistics Quarterly, Vol. 1 (1954), pp. 313-320.
[5]
DRESHER, M . , Games of Strategy: 1961.
Theory and Applications,
1954.
Prentice Hall,
SHAPLEY
28 [6 ]
EVERETT, H., "Recursive games," Annals of Mathematics Study No. 39, (Princeton, 1957), pp. 47-48.
[7]
GALE, D., KUHN, H. W. and TUCKER, A. W . , "On symmetric games," Annals of Mathematics Study No. 24 (Princeton, 1950), pp. 81-87.
[8 ]
GALE, D., KUHN, H. W. and TUCKER, A. W . , "Reductions of game matrices," Annals of Mathematics Study No. 24 (Princeton, 1950), pp. 89-96.
[9]
GALE, D. and SHERMAN, S., "Solutions of finite Annals of Mathematics Study No. 24 (Princeton,
two-person games," 1950), pp. 37-49.
[10]
KAPLANSKY, I., "A contribution to von Neumann's theory of games," Annals of Mathematics, Vol. 46 (1945), pp. 474-479.
[11]
KARLIN, S., Mathematical Methods and Theory in Games, Programming and Economics, Addison-Wesley, 1959.
[12]
MIYASAWA, K., On the Convergence of the Learning Process in a 2 x 2 Non-zero-sum Two-person Game, Economic Research Program, Princeton University, Research Memorandum No. 33 (1961).
[13]
NASH, J. F., "Non-cooperative games," Annals of Mathematics, Vol. 54 (1951), pp. 286-295.
[14]
ROBINSON, J., "An iterative method of solving a game," Annals of Mathematics, Vol. 54 (1951), pp. 296-301.
[15a]
SHAPLEY, L. S., The Noisy Duel: Existence of a Value in the Singular Case, The RAND Corporation, Rm-641, July, 1951.
[15b]
SHAPLEY, L. S., Order Matrices. September, 1953.
I, The RAND Corporation, RM-1142,
[15c]
SHAPLEY, L. S., Order Matrices. September, 1953.
II, The RAND Corporation, RM-1145,
[15d]
SHAPLEY, L. S., A Condition for the Existence of Saddle-points, The RAND Corporation, RM-1598, September, 1955.
[15e]
SHAPLEY, L. 1960.
[15f]
SHAPLEY, L. S., On the Nonconvergence of Fictitious Play, The RAND Corporation, RM-3026, March, 1962.
S.,
Symmetric Games, The RAND Corporation, RM-2476, June,
[16]
SHAPLEY, L. S., "Stochastic games," Proceedings of the National Academy of Sciences, Vol. 39 (1953), pp. 1095-1100.
[17]
SHAPLEY, L. S. and SNOW, R. N., "Basic solutions of discrete games," Annals of Mathematics Study No. 24 (Princeton, 1950), pp. 27-35.
[18]
SION, M. and WOLFE, P., "On a game without a value," Annals of Mathematics Study No. 39 (Princeton, 1957), pp. 299-306.
[19]
VON NEUMANN, J. and MORGENSTERN, 0., Theory of Games and Economic Behavior, Princeton, 1944.
L. S. Shapley’ The RAND Corporation
GAMES WITH A RANDOM MOVE Rodrigo A. Restrepo
§ 1.
INTRODUCTION
In some models of poker investigated by von Neumann [1],
[2], Gillies
[2], Mayberry [2], Karlin [3 ] and others, the strategies are functions of the outcome of a random move.
This move corresponds to the dealing of a hand
from a deck of cards, each possible hand being identified with some point in the real line.
It seems desirable to include some of these examples in a
more general class of games to which a general method of attack is applicable. This paper considers a class of games that includes the first model in [3].
Here the random move is described by two uniformly distributed
random variables with values
x
and
y
in the unit interval.
and minimizing strategies are n-tuples any
g(y) = (g-j_(y), g2 (y)^
• ••.» gn (y))
f(x) = (f-^(x), f2 (x), respectively.
The maximizing . .., fn (x))
These strategies are
designed to fit a situation where, having received some information about the outcome of the random move, each player may select one of several courses of action from a finite set of alternatives,, the number of alternatives being the same for both players.
The number
the first player, knowing only the value Consequently
f
f^(x)
will be the probability that
x, will select the i*"*1 action.
will satisfy the restriction
0 < f^(x) < 1, and if the
different courses of action are mutually exclusive, additional restrictions must be imposed on the strategies. strategies.
Similar remarks apply to the minimizing
Thus, the following strategy spaces may be considered:
29
RESTREPO
30
JF
= {f | 0 < fi (x) < 1,
all
x
and
i}
g
= lg I 0 < g i (y) < 1 ,
all
y
and
i}
n Z f (x) < 1, i=l
all
x]
9 ° = £g € S I -r2 g-f(y) < 1* i=l ±
all
y} .
i = 1 - d-T^T
^
it is
'
A CHARACTERIZATION OF THE OPTIMAL STRATEGIES
Two strategies max P(f, g*) f
fL
31
f*
and
g*
are optimal ifand only
P(f*, g*) = min P(f*, g ) . g
P(f*j g*) = —
2 b. G . (1) + max i=l 1 1 f
if
P(f*, g*) =
Explicitly,
Z f f .(x)cp.(x, g*)dx i=l J 0 1 1
and
(4)
P(f*, g*) =
Z a. F?(l) + min i=l 1 1 g
Z
i=l
J 0 g.(y)Y .(y, 1 1
f*)dy
where
(5)
^(x,
g*) =
+ (Ci - d i )Gi (l) + 2 d iG 1 (x)
and
(6 )
Y i (y, f*) = - b ± + (Ci + d i )Fi (l) - 2 d j F ^ y )
Thus, if the strategy space is
9r, then the strategy
f*
.
satisfies the
following conditions:
0
0
.
if the strategy space is SF°, then the conditions are as follows
32
RESTREPO f •(x) = 0 0 < f^x)
0 J
if
or
cp.(x, g*) > 0
£ *,
These conditions characterize
and
cp.(x, g*) < max cp. (x, g*) j^i J
cp. (x, g*) > max cp. (x, g*) 1 j^i J
and the minimizing strategy
characterized in a similar manner.
g*
can be
With this characterization (due to
S. Karlin), any knowledge about one of the optimal strategies yields informa tion about the optimal strategies for the other player. iterative, and the coefficients
cp^
and
The process is
play a fundamental role.
Some
of their properties are given in the next two lemmas; the proofs are simple computations which are omitted.
LEMMA 2.1.
For each
x,
max cp^(x,g) = (1—x) max (a^, a^+c^—d^) + x max (a^, a^-fc^-kL) g 1 min cp^(x,g) = (1—x) min (a^, a^+c^—d^) + x min (a^, a^+c^-kL) g min £
Y . ( y , f ) = (1—y) min (—b . b . +c . +d .) 1 1 1 1 1
+ y min (—'b 1. , —b1. +c1 .— d .) 1
max Y^( y , f ) = (1—y) max (—b ^ ,—b^+c^-kL ) + y max (—b^ ,—b^+Cj—d^)
LEMMA 2.2.
Let
of the set
E.
x(E) If
denote the characteristic function
d^ > 0, then
cpi (x, X([yi. 1 ])) = (di - c i) (yi - a i) + max [0 , 2di (x - y ±) ] Yi (y. x( [x±, 1 ])) = - ( d ± + c ±) { x ± -
§ 3.
GAMES DEFINED BY
- max [0 , 2di (y - x ±) ].
(P,
$ , S )
In these games the components of each strategy are uncorrelated, and in order to solve the game it is sufficient to find the for each index
i.
a^b^ > 0, for each
minmax
strategies
For simplicity it will be assumed in this section that i.
Furthermore,
if
a^
and
b^
are negative, reversing
GAMES WITH A RANDOM MOVE
33
the roles of the two players one obtains an equivalent game where the corresponding coefficients are positive.
If
a^ > 0,
> 0
then
reversing the orientation of the unit interval (i.e.,
(x —
y)
cp^
and
by sign q
al > 0 ,
(y — x ) )one obtains a game with
> 0 * d^ > 0
and
d^ > 0 ;
f, and
|c^| > d^, then either
q(y> Since
where
a^ + c^ — d^ > 0
c^
if or
f) > 0 g*
f*.
for
is
The case
is equally trivial.
consider now the games where
— d^ < 0 and
Finally,
f.
the characterization of Section 2 yields the optimal
One must
d^ = 0 , then
that
is uniformly best against any
known,
a^ +
if
— b^ + c^ + d^ < 0
t*ie f^rst case Lemma 2.1 shows
g*(y) - 1
< 0,
replacing sign
are constant functions and the game is trivial.
a i + c i~ ^i — all
but
— b^ + c^ + d^ > 0.
a^ > 0 ,
b^
These are games
> 0,
!c^| < d^,
where
cu and
q
are in the unit interval; their solutions are given in the following theorem:
THEOREM 3.1.
Under the given assumptions the game has
solutions of the form
f* = m.x([0 , x ± ]) + X ([x±, 1 ])
s i = n i^(^0, y i ]) + X([yi. 1]) ,
where E.
x(E)
Furthermore, iqiq = 0, and
PROOF. = y^ = q , but
n^
g* minimizes
q(cu,
denotes the characteristic function of the set
f*) = 0.
= ou
or
and
g*
Consider any strategies
f*
= 0
By Lemma 2-2
and
0
0
argument similar to that of Lemma 4.1. completely determined by
can be established by a perturbation To show that the solution is
X*, it is sufficient to observe that setting
GAMES WITH A RANDOM MOVE *
X*
y± = G&i + ^ — - c ^
one completely
can be determined by means of the
determines
37
g* and
cp^(x, g*) .
characterization of Section 2.
Then
f*
In the
indeterminate case where f X*
cp^(x, g*) = max cp^ (x, g*) > 0 , the indeterminacy of J * can be eliminated by the conditions f ' = 0 f°r i- Viewing as a parameter,
these conditions constitute a system of equations whose *
unknowns are
X*
and the values of
f^
in the indeterminate regions.
is no loss of generality in assuming that each
f^
There
is a constant in each of
these intervals. The previous result can be improved slightly. X* = cp^(o* g*)j Lemma 2.1 implies
that
values of
of
X*, the relative order
Indeed, since
a^ > X* >a^ + c^ — d^. y^, ..., yn can
For these
be deduced
from the
following theorem:
THEOREM 4-3.
Let
a^ > 0,
be arranged so that
a^ > a2 > ••• > an *
a^ > X > a^ + c^ — d^ then
for all
y 1 < y2 < ••• < yn
a^ + c^ — d^
|c^| < d^, and let the indices If
i, and if X
for all
y^ = sl^ +
d. - c. ’
if and only if
is a monotone decreasing function of
i
i, — x
PROOF.
By definition, y. = 1 — ^— — i
, and the inequality i
y. > y. J
is equivalent to
d . - Cj > ^
If X;
aj -
X
, the right hand side of (9 ) is a monotone decreasing function of X = a^;
it achieves its minimum value (zero) when
value
when
X =
+ c^ — d^
it achieves its maximum
and in this case the inequality (9)
becomes
ai + ci - di * aj + cj - dj-
EXAMPLE. c^ = — 1
and
The poker model considered
d^ = A^ + 1
Theorem 4.3 are satisfied,
with
in [3 ] has
2 < A^ < ...
X* = 0
< An -
and the optimal
Ai ?i = A T T ~ 2
■
a^ = 2, b^ = 0,
Theassumptions of g*
has
RESTREPO
38 Then
cp_^(x, g*) = \ * + 2d^G*(x), and the optimal
f*
can be deduced
immediately from the characterization given in Section 2.
BIBLIOGRAPHY
[1]
von NEUMANN, J. and MORGENSTERN, 0., Theory of Games and Economic Behavior, Princeton, 1944-
[2]
GILLIES, D. B., MAYBERRY, J. P., and von NEUMANN, J., "Two variants of poker," Annals of Mathematics Study No. 28 (Princeton 1953), pp. 13-50.
[3]
KARLIN, S.,and RESTREPO, R., "Multi-stage poker models," Annals of Mathematics Study No. 39 (Princeton 1957)* PP- 337-363.
[4]
KARLIN, S., "Operator treatment of the minmax principle," Annals of Mathematics Study No. 24 (Princeton 1950), pp. 133-154-
Rodrigo A. Restrepo
The University of British Columbia
A SEARCH GAME Selmer M. Johnson
§ 1.
INTRODUCTION
The following search game was first suggested to the author by Melvin Dresher several years ago. Blue chooses region to hide).
h, an integer, from the set of integers
Red guesses an integer from
1
to
is too high or too low, and repeats until he guesses
1
to
n
(a
n, is told whether he h.
The payoff to Blue
is one unit for each guess by Red (including the last guess
h).
This game
is illustrated in [1], pages 32-35. Progress was reported by the author in a 1958 internal RAND document which presented the solution for
n < 11
using a special notational device
to describe Red strategies. Recently Gilbert
[2] discussed the same game, along with related
problems, and gave its solution for even for
n = 6, were quite lengthy.
n < 6.
He stated that the calculations,
Later, in [3] Konheim computed the
number of "bisecting" strategies for Red.
This does not pertain directly to
solving the game. We present both the improved notational device for describing Red strategies and some recent theorems concerning necessary conditions for opti mality which greatly reduce the size of the game matrix. utions for
n < 10
quite simple.
The case
n = 11
This makes the sol
is more complicated, and
incidentally exhibits a qualitative feature of Blue's optimal strategy con jectured by Gilbert in [2], namely that Blue ought to avoid as well as
n/2.
39
n/4
and
3n/4
JOHNSON
40
§ 2.
NOTATION
At first glance it would appear that this is a multimove game for Red, since after each try he has new information and makes his next move accordingly.
However, a better formulation is to describe a hunting strategy
as a complete pattern of moves which takes care of all possible hiding places for Blue.
Thus,
if
1 < j < n
each with probability integers, denoted by meaning of the
= {S^}-
n
numbers Blue can choose from, n
The following example will illustrate the
S..:
1
2
3
4
5
6
7
Pj
Pi
P2
P3
P4
P5
P6
P7
s. . IJ
2
3
1
3
4
2
3
j
Here Red guesses
3
first.
if too low, he tries the guess when
are the
p^ , then a strategy for Red is an ordered set of
j
6
If too high, he tries
1
for his second guess;
for his second guess, etc., S ^
is the number of
is tried.
Red will play a mixture of these strategies lity
t^.
The payoff,
if Red plays
S^, each with probabin and Blue plays {p^}^ is 2 S^.p.. J j J J
The value of the game is
V = min
max
Z) Z / S . .p .t . = max
{ t j {Pj} i
§ 3.
j
ljP j 1
min
Z/ S
{Pj} {t.} j
i
S ..p .t ..
^
1
PROPERTIES OF OPTIMAL BLUE STRATEGIES
First it is clear from the definition of the game that Blue may play symmetrically about the center of the interval.
a)
Also it is clear that all
Thus, we may assume
Pj = Pn-j+X-
p^
are positive in an optimal Blue strategy.
A SEARCH GAME
41
THEOREM 1.
(2)
px > p2 -
PROOF.
If
p^ < p 2, then Red would always play 2 before 1, so that
these two column payoffs in the game matrix could not be equal. consider any where matches
where
2
1
is played before
2.
Compare
is played at the k t^1 guess rather than
To see this with a related
1, and the rest of
in the relative order of play:
P_a____
pl
p2
k
k+m
t
k+m— 1
r
k— 1
k+1
k
t-1
k+m— 1
r
k— 1
(Note that the values of 2 < j < a, where
(3)
will be reduced by
S^a = S^2 — 1*)
£ j
_______________Pb
(S.. - S..)p.
It can be shown that
1
in the interval
Then
= - p, + m p 2 + £ p. > 0. 1 2 5.
Other properties of
optimal Blue strategies can be conjectured from the list of solutions in Sec. 5, but seem to be difficult to prove in general. holds for
5 < n < 11, and
conjecture that
p^ = 2p2
holds for
p^ > p ^ , 1 < j < n, for
§ 4.
For instance, 7 < n < 11.
p-^ = P 2 + P3
Also, one might
n > 4.
PROPERTIES OF OPTIMAL RED STRATEGIES
In this section we greatly reduce the list of possible optimal Red strategies against any trial Blue strategy.
THEOREM 2.
Suppose at a given stage that Red, playing
S^, has located that
S^
h
on the interval
k < j < m,
and
calls for next playing at
a, left of
the
42
JOHNSON median of the hider's frequency distribution on this interval, and if to the right of
a a.
optimality of
is too small, next playing at Then a necessary condition for
against
(4)
b
{Pj}
is that
S p. > E p.. k 2 p., so that if 2 p. < -~ 2 p. j =k 3 j =b 3 j =k ^ j =k ^ Thus Theorem 3 is proved.
§ 5.
SOLUTIONS FOR
then
a b— 1 2 p . < 2 p., k 3 a+1 3
n < 11
In this section we exhibit optimal strategies and the game value for n < 11.
From (1) it follows that Red can play a given
counterpart which
S^
S^ = 1
equally often. for
j
and
v (2) = 3/2. Case
n = 3-
= (2, 3, 1)
Here only
= (2, 1, 2)
are undominated.
and
S2 = (1> 3, 2)
with
By the remarks concerning symmetry, the
3 by 3 game matrix can be reduced to an equivalent 2 by 2 matrix.
\^Blue
\Blue
Red^\ S1
Thus
P
P2
Pi
2
1
2
1
Case
and n
2
3
= {pj} = {-4, S2
Red\
2
1
3
4
1
2
3
3
becomes
S2
between
Pi
.2,
.4}, t-^
of course. = 4.
= .6, and
t2 = -4, the latter split
Here there
are only
3
undominated strategies
The reduced game matrix is 3 by 2.
\Blue Rech\ S1 S2 S3
equally
V(3) = 9/5.
\Blue Pi
P2
P2
Pi
Red^\^
1
1
2
1
2
3
0
5
3
2
1
3
2
1
4
4
1
3
4
2
0
3
7
S^.
A SEARCH GAME A solution gives p^ = 1 / 4 played with probability Case
n = 5.
1/2
for each
each, and
45 j, while
S2
and
are
V(4) = 2.
The list of undominated strategies
and the reduced
game matrix are as follows:
\B lue
\Blue
R e d \ S1 S2 S3 S4 S5 S6 S7
P1
p2
p3
p2
pl
2
3
1
3
2
3
2
1
2
3
2
1
3
2
3
2
1
4
3
2
each with
4/9, 1/18 Case
5
3
2
4
4
6
1
40
6
4
1
40
4
5
3
3
40
1
4
4
4
40
2
1
3
4
2
4
5
3
41
1
4
3
4
2
3
8
3
45
1
3
5
4
2
3
7
5
46
40
40
20
Thus Blue plays with frequency bability
R e o \
and
(5, 3, 2, 3, 5) and Red plays
each with
probability.
2/9
probability and
p2
p3
p3
V(5) = 20/9.
p2
P1 6
5
4
7
4
49
5
5
4
48
5
7
3
52
4
5
7
49
4
4
9
50
5
3
7
48
3
8
8
55
3
9
7
56 56
4
3
7
11
48
48
48
with pro
and
n = 6.
P1
310
S-^
48
46
JOHNSON
Blue plays a frequency distribution (5, 3, 2, t^ = .6, ty = . 2 , Case
and
n = 7.
2,
3, 5) „ Red plays
The solution for
n = 7, giving optimal
only,
5
23
6
23
5
23
5
23
46
46
46
with frequency distributions as indicated for each player. Case
t-^ = .2,
V(6) = 2.4.
23
V(7) = 23/9-
n = 8.
27 27 27 27
with
27
27
27
V(8) = 2.7. Case
n = 9.
2
1 1 1 1
6
4
6
8
1
31
6
4
8
6
1
31
5
8
5
4
4
31
6
4
7
4
4
31
6
6
5
5
3
31
5
7
3
8
3
31
62 62 62 62 31
is
A SEARCH GAME Here the number of
47
strategies is larger than necessary, but suffices.
V(9) = 31/11. Case
n - 10.
Here
V(10) * 35/12.
2
1
1
1
1
1
1
1
1
2
3
2
3
4
1
4
3
4
2
3
3
2
3
4
1
4
3
2
4
3
\Blue Red\^ S1 S2 s3 S4 S5
2
1
1
1
1
2
6
4
7
7
5
35
1
6
6
5
7
5
35
6
6
6
3
2
4
3
1
4
3
2
4
3
4
6
5
35
2
3
4
1
4
3
4
2
4
3
2
5
7
6
5
7
35
3
2
3
1
4
3
4
2
4
3
3
6
6
5
5
7
35
70 70 70 70 70
Case
n = 11.
Here
V(ll) = 3 -g^.
OO
58 29 29 34 25 22 1
1122
8
1
1122
7
4
4
1122
5
5
7
5
1122
5
7
3
8
3
1122
6
8
3
8
3
1122
54
6
6
6
6
6
6
8
4
6
87
6
6
6
18
6
6
6
7
15
6
The computation appears to get more difficult for yond.
accomplished by the techniques of this paper. total number of Red pure strategies,
(8) with
n = 12
and be
Nevertheless, considerable reduction in the list of Red strategies is
f (n)
For instance,
if
f(n)
is the
the recursion relation
S f(k — 1) f(n — k) k=l
f(0) = f(l) = 1, etc., gives
f(ll) = 58,786
and
f(12) = 208,012.
One could also use a simple explicit formula ((2) of reference
[2]) for
48
JOHNSON
computing
f(n), namely,,
(9)
BIBLIOGRAPHY
[1]. DRESHER, Melvin, Games of Strategy: Hall (1961).
Theory and Application,
Prentice
[2]
GILBERT, E. N ., "Games of identification or convergence," SIAM Review Vol. 4, No. 1, January 1962, pp. 16-24.
[3]
KONHEIM, A. G-, "The number of bisecting strategies for the game (N)," SIAM Review, Vol. 4, NO. 4, October 1962, pp. 379-384.
Selmer M. Johnson The RAND Corporation
THE RENDEZVOUS VALUE OF A METRIC SPACE 0. Gross
§ 1.
INTRODUCTION AND THEOREMS
It is the purpose of this short note to prove a few theorems regard ing average (arithmetic mean) distances of points in a finite collection from some point in a compact connected metric space.
To each such space,
in
fact, corresponds a unique constant which we shall call its rendezvous value. We shall not use the term in the sequel, but introduce it solely for its connotative value in those instances in which the space is equipped with suitable geodesics.
At any rate it adds spice to the title.
Perhaps the theorems are well known, but since they seem not to be to the few people polled (expressions ranged from surprise to total disbelief), it would seem advisable to jot down short proofs of them. A stronger motivation or raison detre for this paper, however,
is
furnished by the not too well exploited fact that game theory can be used as a tool in other branches of mathematics and physics, in this instance.
including geometry, as
In fact, well known results in game theory render the
proofs of the three theorems almost trivial. The theorems we wish to prove can be phrased as follows:
THEOREM 1.
Relative to a compact connected metric space
there exists a unique constant
K
with the property that
given any finite collection of points one can find a point P
such that the average distance of the points in the
collection from
THEOREM 2.
If
P
K
is equal to
K.
is the constant according to Theorem 1
49
50
GROSS of a compact connected metric d
j
then
THEOREM 3.
V. P n i=l 1 can use the same strategy, and upon exploiting the
symmetry of the metric, we obtain
RENDEZVOUS VALUE
51
n (2)
min ^
S
D(xp
P) < V.
At this point connectedness plays a role. P
Since the functions of
in (1) and (2) are really the same function and
since the range of a
real-valued continuous function on a connected set is connected, there exists a
P
where equality is achieved: n i E D(x., P) = V. n i=l 1
Thus,
existence is proved.
To see that no other constant
assume we have another such
K.
(than V) works,
Assume for the moment that
K > V.
Now, for
a game on a compact space it is known that one can approximate to an optimal strategy by a finite mixture, provided the payoff is continuous. this instance, given {xp
..., xR}
that for all
e > 0
Thus in
there exists a finite collection of points
and positive weights
{Xp
• ••* Xn}
summing to unity such
P n E X . D(x., P) < V + e; i=l
the strategy being employed, say, by the minimizing player. We remark that the theorem is true if the space consists of a single point.
But if otherwise, since the space is connected,
many points in every neighborhood, such about each of the
x^
with common denominator points
Xp
above.
N
in particular we can obtain a cluster of Thus, if the
and numerators
i = 1, . . ., N, with
n^
x^
were rational numbers
n^, we can select
of them clustered near
arithmetic average approximating an optimal strategy. continuity of the metric.
there are infinitely
Since, however,
N x^
different to obtain an
This follows by the
the rational numbers are dense in
the reals, we see that this can be done in any event, so that given any e > 0 for all
there exists a finite collection of points P
i
E
N i=l
D(x , P) < V + e. 1
{xp
..., x ^
such that
52
GROSS
But since
K > V, we can choose
e sufficiently small so that the value
cannot be
achieved by any point
P in the collection.
The case
K < V
obviously be treated in the same manner, and uniqueness follows.
K can
This
concludes the proof of Theorem 1.
§ 3.
By
PROOF OF THEOREM 2
the arguments used to prove
Theorem 1, the
K involved in the
statement of Theorem 2 is the value of atwo person zero sum game in each
player independently picks a point
the distance between their choices. satisfies
which
in the space with the payoff being
To show that the value of the game
the lower inequality,we observe first that the compactness of
the
space guarantees the existence of a pair of diametrically distant points
x-^
and
x2 .
1/2.
Let the maximizer play a pair of such, each point with probability
Whether this strategy is optimal or not, we have
K > min ( j D(xr
P) + j
D(x2 , P)).
But by the triangle inequality, etc.
D(x-^, P) + D( x 2 , P) > D(x1 , x 2 ) = d;
whence
To see that
K < d, we observe first that any pure strategy for the minimizer
guarantees that
K < d, since
however, d > 0,
and it remains to show
generality, therefore, take
d
is a
d = 1.
bound on the payoff. that
K ^ d. We can
By assumption, without loss in
However, the assumption that
K = d = 1
leads to the existence of an infinite sequence of points in the space all one unit apart from each other (by repeated application a sequence cannot contain a convergent not compact, contrary to hypothesis. of Theorem 2.
of Theorem 1).
But such
subsequence, and the space is therefore Thus
K < d.
This concludes the proof
RENDEZVOUS VALUE § 4.
53
PROOF OF THEOREM 3
The hypothesis of Theorem 3 is not satisfied unless can without loss in generality assume that
d = 1.
theorem in game theoretic language, as we can,
d > 0, so we
If we rephrase the
in view of the previous
arguments, we are required to find a suitable compact connected metric space such that the game value is a given number
K
on the interval
(^, 1].
In
fact, the space we shall select will be homeomorphic to the closed unit interval.
Consider the closed unit
interval
[0, 1].
One verifies that if
we select ( X + l ) |x— y | D (x, y) = ------------ ,
X
as the payoff,
X|x—y| +1
then
the Euclidian metric.
0 0
if
|x — y|
evaluates
is continuous etc., the new space
is still connected and compact and has diameter 1, for any choice of X = 0,
as
\
the value of the game is &
the value of the
X-
If
and it is an easy exercise to verify that
game tends to 1.Since thevalue of the game is
readily shown to be a continuous function of the game parameter with the appropriate choice
thereof obtain a game with
This concludes the proof of
Theorem 3.
we can
the prescribed value.
BIBLIOGRAPHY
[1]
GLICKSBERG, I., "Minimax theorem for upper and lower semi-continuous payoffs," The RAND Corporation Research Memorandum, RM-478, October 1950.
0. Gross
The RAND Corporation Santa Monica, California
GENERALIZED GROSS SUBSTITUTABILITY AND EXTREMIZATION Hukukane Nikaido
§ 1.
This paper is [15,
16].
INTRODUCTION
a sequel to the two previous papers by this writer
It may also be regarded as an answer to the question how far we
can go without fixed point theorems when handling systems of inequalities which generalize those arising in game theory. Ever since recent contributions
[1, 6 , 7, 8 , 10, 13, 14], with the
aid of fixed point theorems or their equivalent propositions, gave general conditions for the existence of competitive equilibrium, attention has shifted to the detailed observation of competitive economic systems under rather special conditions such as gross substitutability.
Several interesting
results have been quite recently obtained along this line (e.g., 11, 12]). line
The purpose
above,
of this paper, which is also
[2, 3, 4, 9,
in accordance with the
is to give an elaborated version of the existence theorem of
competitive equilibrium in the case of generalized gross substitutability. A criterion,
in the form of a boundary condition, for the existence of
equilibrium will be given, so powerful that it can be still effective even when the known fixed point techniques break down.
This criterion is also
useful to locate equilibrium within a given, possibly small, open subset of the whole price set.
A rearrangement of the argument also entails the unique
determination of some system of functions by their boundary values^ a situa tion similar to those observed in the theories of analytic functions and harmonic functions.
Generalized gross substitutability is a unified
generalization of skew symmetricity and gross substitutability.
Finally,
the
dynamic implication of generalized gross substitutability will be made clear for the Brown-von Neumann differential equation, which was originally devised to solve zero-sum two-person games. 55
56
NIKAIDO Our method is extremely elementary and consists of the extremization
of the sum of the squared positive excess demands of goods.
It takes
advantage of a simple fact that some quadratic form is negative definite, which was observed by McKenzie
[9].
This fact can be derived from the
following well-known basic theorem on matrices with nonpositive off-diagonal elements, which reads as follows: n x n
For any
matrix
B = [b-jj ], b ^
^0
(i ^ j),
the following three conditions are equivalent: (I)
Bx > 0
(II)
for some nonnegative vector
B hasthe nonnegative inverse
(Ill)
B ^
The Hawkins-Simon condition holds,
x ^ 0. ^ 0. i.e.,
all the principal minors are positive. As is well-known,
this basic theorem can be directly proved by bringing
into a triangular matrix,
B
through elimination, without any reference to the
Frobenius theorem on nonnegative matrices.
§ 2.
EXISTENCE AND LOCATION OF EQUILIBRIUM
2.1We shall goods, labeled
be concerned with a competitive economy where all
i = 1,
2, ..., n (n^ 2), are generalized weak
substitutes in the sense as defined below. by a nonnegative n-vector attention to a set are defined.
P
The price system will be denoted
p = (p^, P2 , ••., Pn ) > 0.
We shall pay special
of price vectors in which the excess demand functions
In the sequel, all topological considerations will be done with
regard to the relative topology of the nonnegative orthant induced by
gross
of
Rn , as
Rn , unless otherwise indicated.
The basic assumptions throughout this paper are as follows: (a) origin
0
P
i.s a nonempty subcone of the nonnegative orthant
deleted, and it is open in (B )
R™, the
R^.
The excess demand functions
E^(p)
(i = 1 , 2 ,
..., n)
are
single-valued continuous functions and have continuous partial derivatives BE.
in
P, which will be denoted by (y)
E^(p).
Positive homogeneity of degree
Ei (Xp) = \m E i (p)
for
X > 0, p e P.
m, 0 £ m 0 (i ^ j)
2.2
i.e. ,
%
(6)
everywhere in
P-jE^p) = 0
identically in that is,
P.
In the terminology of economists,
gross substitutability
prevails when
E ^ (p) ^ 0 (i ^ j).
for all
when the Jacobian matrix of the system of functions
i, j
skew symmetric.
2.3
In the both
On the other hand, E ^ (p) 4- Ej^(p) = 0
cases condition
(e)
E^(p)
is
is clearly true.
The central problem at issue here is the possibility and
stability of a competitive equilibrium. price vector,
P.
p € P
is said to be an equilibrium
if
(2.1)
Ei (p) 0.
theorem on the existence of competitive
equilibrium premises only the continuity of the excess demand functions and the Walras law, and not any special condition such as gross substitutability. But it heavily relies upon the simpler topological structure of the domain of the excess demand functions such as convexity or acyclicity.
Compared with
it, the novelty of our result lies in the fact that at the cost of assuming a type of substitutability the domain of
E^(p)
complicated nature than as is usually assumed.
is allowed to be of more P
need neither be convex nor
even acyclic, so that our result seems to be more than an alternative proof. The figure on the right illustrates the intersecting portion of a the normalizing hyperplane
P n 2
with p. = 1.
1=1 1
Hol es
58
NIKAIDO 2.4
[9]
As a preliminary step, a lemma, which is observed by McKenzie
for the case of
LEMMA.
m = 0 , will be given for a variety of values of
Under conditions
(a ),
(S ),
(y ),
(6 )
m.
and ( e )
the following results are true: [i]
When
for any p e P.
(2.3)
0 o|
Then, the quadratic form
£ E..(p)?.§. i*jeN(p) J J is negative definite, provided [ii]
When
m = 1, the
(2.4)
N(p) ^ ip.
quadratic form
£ E..(p)?.?. i,j=l 1 J is negative semi-definite at every
PROOF. our case.
p e P.
The proof will be done by adapting that of McKenzie [9] to
Upon differentiation of equation
2 p^E^(p) = 0
given in (6) we
have
+ E. (p) = 0 i=l 1 1J On the other hand,
(j - 1, 2 , ..., n).
3
(y) together with (B) implies, by virtue of the Euler
theorem on homogeneous functions, n £ Pn-E ii (p) - “ E, (p) = 0 W 1 J1 J
(j * 1 > 2 i •••. »)•
Hence summing up these equations gives
(2.5)
n £ e . . ( p ) p . + (l-m)E.(p) = 0
i=l where
(j = 1, 2,
. .. ,
n).
3
e^j (p) = E ^ (p) + E ^ ( p ) .
The subsequent portions of the argument
will be separately developed for [i] and [ii].
SUBSTITUTABILITY AND EXTREMIZATION The case of [i].
(2.6)
By
£ ieN(p)
1J
59
Relation (2.5) can be rearranged to
1
— e . .(p)p. = (I—m)E. (p) + £ e..(p)p J i^N(p) 1J 1
(jeN(p)).
(e ),
for
e . .(p) £ 0 for i£ N(p), j e N(p), sothat £ e..(p)p. >0 1J “ itN(p) 1J 1 = j e N(p) in view of being nonnegative. Furthermore, (1—m)Ej (p) > 0
for
j e N(p), since
for any
1 > m.
Thus
the right-hand side of (2.6)is positive
j e N(p), that is
(2.7)
£ -e..(p)p. > 0 , ieN(p) 1J 1
Since the off-diagonal elements of non-positive by this matrix.
(e),
condition (I)
Therefore,
p. ^ 0 1 "
(ij jeN(p)).
the matrix
[— e ^ ( p ) ] (i,jeN(p))
are
in the foregoing section is satisfied by
the matrix satisfies also the Hawkins-Simon
condition (III), so that all the principal minors of
[— e ^ ( p ) ]
are positive.
This proves that (2.3) is negative definite, because (2.3) = i £ el i (p)?i§ r 2 i.jeN(p) 1J 1 J The case of [ii]. Since
e > 0
5^
be an arbitrary positive number.
reduces to
n).
We rearrange (2.8) to
(j = 1, 2 ,
. .
n ),
are Kronecker's deltas.
By ( a ) ,
P
is open in
R^.
Therefore, P
of whose components are positive, and furthermore, regarded as a limit point of the former. definite at any (8)
(2.5)
(j = 1, 2 ,
n £ (eSj. - e. .(p))p. = ep i=l ij iJ J
(2.9)
where
1,relation
n £ e..(p)p. = 0 i=l 1J 1
(2 .8 )
Let
m =
p e P
with
in the same way
every point of
P
can be
Thus, once (2.4) is negative semi-
p > 0, the continuity of
assures that the same is true everywhere in Let us
contains some vectors all
e^j(p)'s
implied by
P.
now suppose that p^ > 0 (j = 1, 2, ..., n)
in (2.9).
Then,
as in [i], it can be shown that the principal minors of the
60 n x n
NIKAIDO matrix fe5ij — e -jj (p) ]
are
positive.
Hence
£ (e..(p) — 0 6 ..)?.?. 0, in P. z i,j=l 1J 1 3" 2.5
e > 0,
this
Q.E.D.
Next we shall give a boundary condition for the existence of a
competitive equilibrium in
P.
Let n
( 2 . 10 )
f ( P) = S
1=1
e . ( P) 2 , 1
where
(2.11)
0i (p) = max [Ei (p), 0]
(i = 1, 2, ..., n ) .
Throughout this paper, as in [5, 15, 16], the function
$ (p)
will play an
important role. Boundary Condition p € P, k P,
(*)
on
$ (p).
For any nonzero boundary point
if any exists, and for any sequence
there exists some
q e P, depending possibly on n
(2 .12)
£
i=l
(2.13)
{pV 3 p
in
and
P
converging to
Ip ]
such that
n p. =
1
£
i=l
q
1
$ (q) < lim sup $(pV ). v -» 00
THEOREM. condition
If ( a ) , (*)
(3 ),
(y ),
(e)
and the boundary
are fulfilled, then there is an
equilibrium price system (2 .1)
(6 ),
p
in
P
which satisfies
and (2 .2 ).
PROOF. Let S be the intersection of n 2 p. = 1 . Clearly we have
hyperplane
i=i1 inf $ (p) = 6 ^ 0 . peS
P
with the normalizing
p,
SUBSTITUTABILITY AND EXTREMIZATION Take a
sequence
may assume that naturally
{pv }in {pV ]
p £ P.
(*), there is a
S
such that
lim $ (pV ) = 5.
itself converges to a limit p.
On the other hand, p e P. q e S
for these
But this yields a contradiction:
p
61
and
Since If
p i S, then
Thus, by the boundary condition
{pV }
such that (2.13) is valid.
6 £ $ (q) < lim $ (pV ) = 6 .
p e P,
and continuity implies $ (p) = 6.
p = p
subject to the condition
pV e S, we
Therefore,
v ~,co
That is, $ (p)is minimized at
p e S.
Since
P is open in
R^,
the
following marginality conditions hold:
(2.14)
[||-] ^ £ pk [|i-l ^ U p jJP=P " k=l k U Pk Jp=p
Since
$ (p)
0
- 1- 2,
is positively homogeneous of degree
n).
2m, the right-hand side of
(2.14) equals
2m$(p), by the Euler theorem on homogeneous functions. On the x n other hand, in view of (2.10) and (2.11), we have -r— =2 I 0-(p)E..(p) 3Pj i=l 1 (j = 1, 2, ..., n), so that (2.14) reduces to n £ S-rCpOE..^) ^ m $ ( p ) i=l 1 1J
(2.15)
Multiplying the
(j = 1, 2,
j*"*1 inequality of (2.15) by
0j(p)* we have
n £ e . .(p)e.(p)e.( p ) ^ m$(p) i,j-i
(2.16)
Now, if
1 > m ^ 0, supposing that the set
..., n).
n £ e.(p). j=i J
N(p) = {j | E^(p) > 0}
nonempty, and in view of [i] in the foregoing lemma,
is
(2.16) leads to a
contradiction n
o >
Also,
if
£
,
i)jeN(p)
e . . ( p ) ei ( p ) e i (p) ^ m#(p)
xj
x
j
-
£
j=1
e . ( p ) ^ o. J
m = 1, by [ii] in the lemma, the left-hand side of (2.16) is n so that $ (p) 2 0.(p) £ 0. Therefore, in all the cases we have j=i j (2.2) is an immediate consequence of (2.1) and (6). Q.E.D.
nonpositive, (2il).
2.6
The following corollaries give some special but important
cases on which the boundary condition
(*)
works well.
NIKAIDO
62 COROLLARY 1.
Suppose that a system of functions
which satisfies
(a),
( 8) ,
(v),
( 5 ) and ( e )
in
also fulfills the following boundary condition For any nonzero boundary point an
i
lim E.(p) = + 00• p-p equilibrium price vector in P.
The
validity of
nonzero boundary point of
(*)
P (**):
p e P, ( P, there is
such that
PROOF:
E^(p)
Then, there is an
(**) implies that
lim $ (p) = + 00
- , P"*P p e P, f P, ifany.This surely means
so that thetheorem applies to
COROLLARY 2. Suppose that
the
for any
validity
the present case.
Pas well as
its closure
minus the origin is contained in a larger set where E^(p)'s
are still defined and continuous.
Suppose,
furthermore, that the
system of functions
which satisfies
(8), (y), (6) and (e) in
(a),
E^(p) P
also fulfills the following boundary condition (***): For any nonzero boundary point some
q € P, depending on
p e P, ^ P, there is na n p, such that 2 p. = 2 q. i=i 1
and
$ (q) < $ (p).
vector in
PROOF-
i=i
1
Then, there is an equilibrium price
P.
Since this time
E^(p)'s
the boundary (minus the origin) of
P, (*)
are defined and continuous even on is equivalent to
Corollary 1 includes the most familiar case in which totality of all positive vectors.
(***). P
equals the
Corollary 2 gives rise to the location of
an equilibrium within a possibly thin neighborhood cone
P.
It is also
noted that a version of the existence theorem as considered by Arrow and Hurwicz [4], in which
E^(p)'s
are allowed to take an infinite value, can be
easily reduced to Corollary 1, if generalized gross substitutability is assumed.
63
SUBSTITUTABILITY AND EXTREMIZATION § 3.
3.1 functions values.
DETERMINATION OF FUNCTION VALUES BY BOUNDARY VALUES
In this section it will be observed to what extent a system of
E^(p)
satisfying (a), (S) and (y)
is determined by their boundary
As before, all the topological concepts should be understood in the
relative topology of
R^.
Denote by
normalizing hyperplane with
THEOREM.
=
and
S
PROOF.
the intersections of the
P, respectively.
E^(p)'s
0 ^ m < 1.
and
satisfy
(a), (6), (y),
Then, unless
1, 2, ..., n) everywhere in of (2.10) is maximized subject
E^(p) =
P, the function to
p
Suppose that a maximizing point
p
point of
e
S
at no
P.
(3), (y )j (6) and (e)
hold in
[tpj]p=P ^
(3-1)
and
Suppose that
(6) and (e)
0 (i $ (p)
P
S
lies in
Pk[fpplp=p
(J
~
Z ’
equality holds in the j*"*1 relation in (3.1) unless that
$ (p) = 0.
In fact, if
$ (p) > 0, the set
Since (2.7) holds for
immediate that
p. > 0
for
Since (a)*
P, we have the marginality condition
■ ■ ■ ’
which is the counterpart of (2.14) in the maximizing case.
nonempty.
P.
p = p
and
—
pK = 0.
n>’ It is noted that We wish to show
N(p) = {j j Ej (p ) > o}
is
(p) ^ 0 (i ^ j), it is
j e N(p), so that
[% V p = up pk[tyP=p
£ n
Z)
A e. .( p ) e . i.jeN(p)
Therefore, 0 = § (p) = max $ (p) (a),
(/3 ) ,
(y) and
(b),
( p ) e . (p)
over all
implies that
= m$(p)
n £ j=l
e.(p)
3
>
o.
p e S, which, combined with
E^(p) = 0 (i = 1, 2, ..., n)
everywhere
64 in
NIKAIDO P.
3.2
The following corollaries are some of the immediate consequence
of the theorem.
COROLLARY 1. G^(p)
Let
F^p)
(i = 1, 2,
(i = 1, 2,
..., n)
and
satisfying
(a ),
common
Suppose furthermore that they are defined
P.
(R )
. . ., n)
be two systems of functions
and continuous in
(y )
and
with
m < 1
in a
S, and
n
n p.F.(p) = E p.G.(p) i=l 1 1 i=l
E
(3-2)
(3-3)
(i * 3 )
everywhere in (i = 1, 2,
P.
..., n)
Then, for
if
F^(p) = G^(p)
p e S, ^ S, we have
(i = 1, 2,
Fi (p) = G.(p)
everywhere in
PROOF. corresponding
Let
identically in (i = 1, 2,
P.
Ei (p) = F j.(p) - G ^ p )
$ (p)
is continuous on S
maximized subject to
p e S
P, clearly
..., n)
. . ., n)
for
at some $ (p) > 0.
(i = 1, 2,
n).
which is compact, sothat
p.
Unless
E^(p) = 0 (i
p e S, i S, this
all the assumptions
of the theorem in P.
(i = 1, 2,
identically in P.
COROLLARY 2.
$
(p)is
= 1, 2, ...,
n)
Since, by assumption, E^(p) = 0 p
must lie in
result is in contradiction to the above theorem, because
..., n)
The
Therefore
P.
But this
E^(p)'s
satisfy
F^(p) — G^(p) *E^(p)
Q.E.D.
Except for the system of identically
vanishing functions, there is no system of functions
=0
SUBSTITUTABILITY AND EXTREMIZATION Ei (p)
satisfying
0 £ m < 1 vectors
PROOF.
and
P
(a ),
(8 ),
(y ),
(6 )
if
consists of all nonzero nonnegative
p > 0.
Since this time
S = S c p, the corresponding
p e S
takes on a maximum subject to
It should be noted, however, that if
P
p > 0, conditions
and ( e ) ,
(a ),
(8 ),
(y ),
p e P.
at some point
the above theorem, E ^ p ) = 0 (i = 1, 2, . . ., n)
functions.
(e ),
and
65
(6 )
$ (p)
really
Therefore, by
identically in
P.
Q.E.D.
consists of all positive vectors are met by systems of nontrivial
The following system of functions provides us with an example.
E, (p) = 1- 2 aiiP}+ m _ Pi (i = 2< n )» where a., £ 0 (i + j), n i j=l 2 a. . = 1 (j = 1, 2, . . ., n) and 1 m ^ 0. On the other hand, the most i=l 1J familiar example of nontrivial systems satisfying these conditions for m = 1 on the totality of all nonnegative vectors
p > 0
is undoubtedly that
arising from the skew symmetric payoff matrix J n person game: E.(p) = 2 a..p. (i = 1, 2, ..., n ) . 1 j=l J § 4.
4.1
p(t) e S (t ^ 0)
has a global solution p(0).
(8),
p(0) = p° e S
P
(in
p^.
Since the mapping
is assumed to be open in Rn ) .
R^,
Furthermore, in view of
p - |p| : the set and
(a)
(B),
satisfy the Lipschitz condition in any compact
lying entirely in
Q.
Therefore, by virtue of the
Cauchy-Lipschitz existence theorem, the modified equation
(4.2)
= ei(IPl) ” Pi
has a local solution positive number.
Next, let t
> 0.
p(t)
t ^ 0), with
^
= l ’ 2’
p(0) = p°, where
a
This means that this
p(t)
is a p(t) e S
It is readily seen, similarly as in [16], that
t e [0, ct].
for
p(t) (cr
ek ( l p D
is a local solution of (4.1).
be any local solution of (4.1) defined in
[0,
t
],
where
Then, upon differentiation and taking into account the relations
p(t) e S, ( y )
and
9i (p)2 = ei (p)Ei (p), we have n
n
(4.3)
in
[0,
t
]-
By the lemma in Section 2, the right-hand side is nonpositive,
SUBSTITUTABILITY AND EXTREMIZATION so that
$(p(t))
bound of all
t
continued to
[0,
to for
is nonincreasing in
[0,
t
t
].
Suppose that
Let
pV g T
and
p g S, that is, r
Since
p(t)
lim pV = p
g
be the least upper
p(t)
g S.
can be
can be continued
r = |p |p
_
is closed in
w
p(t) (cr ^ t ^ 0)
uu < + 00.
V-co
implies
Let
for which the local solution
[0, uu), the above result assures that t g [0, uu).
].
67
g
S, $ (p) £ $(p(0))}
Then, assumption
(“ )
_
S.
Since
S
is compact, r
Thus, in the light of the compactness of F, we can let n I0•(p) ~ P* 2 9i (p)I ^ K on T for some K > 0. Then, for any 1 1 k=l k t2 e [0, uu), we have
is also
compact.
t2 lpi (t2 ) - P ^t^)!
n Iei (p) - P ±
£
t,, 1
0k (p)|dt £ K|tx - t2 |,
the extreme right-hand side of which tends to zero as
t^, t2 -* w.
Hence
lim p(t) exists and the limit belongs to F. This implies the possibility t-uu to continue the solution beyond uu, so that uu must be 4- 00. Now take any global solution
p(t).
Then,
(4.3) holds over time,
and we have
2 ft
*
^ E . .(p) 0 • (p) 0 • (p) i,jeN(p)
t - + 00. p(t)
1 > m > 0)
(if
m = 1).
— 2§(p)^2
This proves,
(if
in the light of the lemma in Section 2, that
Since
p(t) e r
over time, and
r
$(p(t)) - 0
is compact, the distance from
to the set of all equilibrium vectors converges to zero as
infinity. nonnegative
Q.E.D.
It is finally noted that, if
p > 0, assumption
dispensed with, because
(«>)
as
P
t
tends to
consists of all nonzero
does not become effective and can be
S = S.
BIBLIOGRAPHY
[1]
ARROW, K. J. and DEBREU, G-, "Existence of an equilibrium for a competitive economy,11 Econometrica, Vol. 22, No. 3 (1954)* PP- 265-290.
[2]
ARROW, K. J., BLOCK, H. D. and HURWICZ, L., "On the stability of the competitive equilibrium, II,11 Econometrica, Vol. 27, No. 1 (1959), pp. 82-109.
NIKAIDO
68 [3]
ARROW, K. J. and HURWICZ, L., "Competitive stability under weak gross substitutability: The 'Euclidean distance' approach," International Economic Review, Vol. 1, No. 1 (1960) pp. 38-49.
[4]
ARROW, K. J. and HURWICZ, L., "Some remarks on the equilibria of economic systems," Econometrica, Vol. 28, No. 3 (1960), pp. 640-646.
[5]
BROWN, G. W. and von NEUMANN, J.,"Solution of games by a differential equation," Annals of Mathematics Studies, No. 24, (1950), pp. 73-79.
[6]
DEBREU, G., Theory of Value,
[7]
GALE, D., "The law of supply and demand," Math. pp. 155-169.
[8]
MCKENZIE, L. W. , "On equilibrium in Graham's model of world trade and other competitive systems," Econometrica, Vol. 22 (1954), pp. 147-161.
[9]
MCKENZIE, L. W. , "Matrices with Dominant Diagonals and Economic Theory," Proceedings of the First Stanford Symposium, (Stanford University Press, 1960), pp. 47-62.
(John Wiley,
1959). Scand. 3 (1955),
[10]
MCKENZIE, L. W . , "On the existence of general equilibrium for a competitive market," Econometrica, Vol. 27 (1959), pp. 54-71.
[11]
MCKENZIE, L. W- , "Stability of equilibrium and the value of positive excess demand," Econometrica, Vol. 28, No. 3 (1960), pp. 606-617.
[12]
MORISHIMA, M . , "On the three Hicksian laws of comparative The Review of Economic Studies, Vol. XXVII, 3 (I960)* pp.
[13]
NIKAIDO, H., "On the classical multilateral exchange problem," Metroeconomica, Vol. 8, No. 2 (1956), pp. 135-145.
[14]
NIKAIDO, H . , "Coincidence and some systems of inequalities," Journal of the Mathematical Society of Japan, Vol. 11, No. 4 (1959) pp. 354-373.
[15]
NIKAIDO, H . , "On a method of proof for the minimax theorem," Proceedings of the American Mathematical Society, Vol. 10, No. 1 (1959), pp. 205-212.
[16]
NIDAIDO, H., "Stability of equilibrium by the Brown-von Neumann differential equation, ' Econometrica, Vol. 27, No. 4 (1959), pp. 654-671.
statics," 195-201.
Hukukane Nidaido The Institute of Social and Economic Research Osaka University
ADAPTIVE COMPETITIVE DECISION Jack L. Rosenfeld
§ 1.
INTRODUCTION
During recent years, much interest has been shown in a class of problems called by the author general adaptive processes.
In these processes
some measure of performance, or "return," is increased as the experimenter gathers more information about the process. however,
The characteristic feature,
is that the actions taken by the experimenter determine both the
actual return to him and the type of information gathered by him. armed bandit problem described by Bradt et al.
The two-
f1 ] is a. good example.
The
question posed is how to decide which of two slot machines to use at each of n
trials in order to maximize the total return.
nothing or one dollar when played.
Both machines pay either
The a priori probability distributions of
the payoff odds of each machine are available to the experimenter. problem is a finite length general adaptive process.
This
Other general adaptive
processes are described in [2] to [6]. An adaptive competitive decision process consists of an person,
zero-sum game that is to be played an infinite number of times.
each step (a single play of the
m x n
selected by his opponent.
After
game), the payoff is made and each
player is told what alternative (pure strategy of the
advance.
m x n, two-
m x n
game) was
The payoff matrix is not completely specified in
The nature of the uncertain specification of the matrix and the
process by which the uncertainty can be resolved form the heart of the adaptive decision process.
Some of the payoffs of the matrix are unknown to
the players when the game is begun.
Unknown payoffs are selected initially
according to a priori probability distributions, these probability distributions.
If
is one of the unknown payoffs,
players do not learn the true value of *
and players are told only
a^j
until player
A
the
(the maximizing
Agencies supporting this research are listed at the end of the paper. 69
70
ROSENFELD
player) uses alternative alternative B loses
j
i
and player B (the minimizing player) uses
at some step of the infinite process.
Then A receives
a ij» and both players are told the true value of
no longer unknown.
a±y
a ^ ;
so that it is
Of course, when all the unknown payoffs have been
received, the process is reduced to the repeated play of a conventional m x n, two-person, zero-sum game. (One can visualize permanently recorded. matrices.
a stack of matrices, each with all its payoffs
Some of these payoffs are hidden by covers on all
A probability is assigned to each matrix in the stack.
players know this probability distribution.
The
One of the matrices is chosen
according to the probability distribution by a neutral referee, and that matrix is shown to the players with the covers in place.
The game is played
repeatedly until a pair of alternatives corresponding to one of the covered payoffs is used.
The cover is then removed, and the play resumes until the
next cover must be removed, and so on. remains.
This process continues until no cover
The completely specified game is then repeated indefinitely.) There are two subclasses of adaptive competitive decision:
the
equal information case, in which A and B are given the same a priori knowledge about the unknown payoffs; and the unequal information case, in which their a priori data are different.
(The ’’stack of matrices” illustration is not
valid in certain unequal information cases.)
One example of the unequal
information subclass is
the situation in which Bknows the true value of
some payoff that A does
not know.
Adaptive competitive decision processes belong to a class of problems involving the repeated play of certain game matrices; these processes are all infinite games that have supinf solutions [7, 8, 9].
§ 2.
MEASURE OF PERFORMANCE
It appears that A should play so as to receive a large payoff, learn the payoffs that are unknown to him, and prevent B from learning the payoffs that are unknown to B.
Also, A should extract information about the payoffs
unknown to him by observing the alternatives that B has chosen during previous steps, while not divulging to B, by the alternatives A chooses, any information about the payoffs unknown to B.
A quantitative measure of
ADAPTIVE COMPETITIVE DECISION performance has been found, such that
A
71
can essentially satisfy these goals
by selecting a strategy that minimizes the measure of performance. measure is called the mean loss.
This
Player B should select a strategy that
maximizes the mean loss. Before the mean loss is defined,
it must be noted that the players
of adaptive competitive decision processes lose no flexibility by restricting their strategies to "behavior strategies."
A player is said to be using a
behavior strategy if at each step he selects a probability distribution over his tive.
m
(or
n) alternatives and uses that distribution to select an alterna
The distribution he chooses may depend upon his knowledge
of the
history of the process, which consists of the alternatives selected by both players and payoffs received at all preceding steps.
(The analysis used by
Kuhn [10] is easily applied to adaptive competitive decision processes, which are infinite games of perfect recall,
to reach this conclusion.)
Because
behavior strategies are completely general for adaptive competitive decision processes, the following discussion will assume that both players restrict themselves to the use of behavior strategies. The probability distributions used by players
A
and
B
at the k
th
step are respectively denoted by
Here
p^ (q^) is the probability that x.U at the k step. Hence,
Note that
k
A (B)
is a superscript— not a power.
selects alternative
1c
In general, p
and
i (j )
q
k
depend
upon the past history of the process. The value of the payoff matrix is denoted by maximum expected return that
A
the unknown payoffs were known. values of the unknown payoffs. step when
A
uses
p
k
and
B
v; it represents the
could guarantee himself at one step, if all Of course, v
is a function of the true
The expected return to player uses
q
k
is denoted by
k
r :
A
at the
k*1*1
72
ROSENFELD
k
5?
r Since some of the payoffs
"£
a^j
?
A
kk
pi V i J
are unknown, r
and the values of the unknown payoffs.
' 1c
1c Ic p , q ,
is a function of
The term
Tk k L = v — r
is called the single-step loss at the k*"*1 step; it is the difference between the expected payoff that
A
could guarantee himself if the values of the
unknown payoffs were known and the expected payoff
A
does receive.
ic. single-step loss, L , represents the expected loss to
A
at the
k
The
ttl.
step
of the process due to his lack of data about the unknown payoffs. The loss for
N
steps of the process, called the N-truncated loss,
LN' is Ln W
h
N k 2 Lk . k=l
The N-truncated loss is a function of the true values of the unknown payoffs as well as the strategies used by both players.
The mean value of the
N-truncated loss, with respect to the probability distribution of the unknown payoffs is
%
where
P
- J%dP
,
denotes the cumulative distribution function of the unknown payoffs.
is a function only of the strategies of
A
and
B.
The mean N-truncated
loss can also be written
rn (1)
T"N = imNv — L N
where kth
r
k
and
—
v
2 yr^ k=l
,
are the mean values of the expected return to
step and the value of the payoff matrix, respectively.
were to continue for
N
steps and then terminate,
A
at the
If the process
an optimum strategy for
ADAPTIVE COMPETITIVE DECISION player
A
73
would be the one that maximizes the mean value of the sum of his
expected returns at each step.
According to Equation 1, this is also the
strategy that minimizes the mean N-truncated loss. strategy maximizes
Conversely, B ’s optimum
L^.
Because the adaptive competitive decision process involves an infinite repetition of the game,
the mean N-truncated loss is useful only if
it can be extended to an infinite number of plays. approaches infinity of performance that
A
exists,
If the limit as
N
then this quantity is the measure of
should try to minimize and
B
to maximize.
This
measure is called the mean loss, L:
L = lim L,, . N -o o
in
It will be shown for the equal information case that a supinf solution exists:
(2)
where
L
and
respectively,
Sg
opr
= inf sup L = sup inf L , o o c q A B B A
represent all possible mixed strategies of
A
and
for the infinite game of adaptive competitive decision.
B, LQpt
may be negative as well as positive or zero. Measures of performance other than the mean loss (e.g., the mean sum of discounted expected returns) can be used.
The strategies resulting
from the optimization of these other measures will differ from those arrived at by optimizing the mean loss.
However,
the mean loss has been found to be
a very useful measure.
§ 3.
EQUAL INFORMATION —
SINGLE UNKNOWN PAYOFF
The following intuitive argument presents the essence of the more formal proof that follows.
This matrix is used as an illustration.
game is to be played repeatedly. B
1
a1 h 1 2
0 - 2
2
0
Pr (an =
=
k
Pr (an = ~1^ = I
The
74
ROSENFELD
Thus
v = -1,
Consider the auxiliary game defined by the matrix
v ~ a 21 + ^
v ~ a 22 + ^
1.5
L - 1
L - 1
L + 1
What relationship does this auxiliary matrix have to the original process? Let
L
be the mean loss associated with the competitive decision process,
a mean loss exists. for that step is not received.
if
When one step of the process is played, the mean loss
v — a i f
a-^
is received, and
v — a^
if
a-^
is
In the former case, the process terminates with no further
loss, because both players should use optimum strategies from the second step on.
If
a-Q
is not received,
the mean loss from the second step on is
L,
because the situation faced by the players is identical to the situation faced by them before the first step.
This reasoning leads to the auxiliary
matrix. Players
A
and
B
should be as willing to make one play of the
game specified by the auxiliary matrix as they are to participate in the original process.
Furthermore, the minimax value of the auxiliary matrix
should equal the mean loss for the adaptive competitive decision process upon which that matrix is based
(y(L )
y(L) = L .
(3)
Note that
A
is the minimizing player of the auxiliary matrix and
maximizing player, The value of L
denotes the value of the auxiliary matrix):
L
since the payoff represents a loss to
A
B
is the
and a gain to
that satisfies Equation 3 is called the optimum mean loss,
The minimax value of the auxiliary matrix for the example is as
follows: -CL)2 + 3 •5L + 0.5 y(L) =
if
L < 2-5
if
L > 2. 5 .
-L + 4-5 L - 1
B.
ADAPTIVE COMPETITIVE DECISION Therefore, L
75
. = i. opt ^
Because neither player's information about the process changes from one step to the next,
it seems reasonable that each player should repeatedly
use one probability distribution for his alternatives before the unknown payoff is received, and afterwards repeatedly use the minimax distribution for the completely known matrix.
Strategies that consist of the repeated use
of one distribution until an unknown payoff is received, and then another repeated distribution until the next unknown payoff is received, and so on, are called "piecewise-stationary."
The first segment of
A's
optimum
piecewise-stationary strategy is the distribution that minimizes the expected payoff from the auxiliary matrix, and expected payoff. -Jr = LQ pt
B's
first distribution maximizes the
These strategies, of course, are functions of
is substituted for
L
L.
When
in the auxiliary matrix for the example,
the
minimax strategies are found to be
_ ,1 po “ ^2’
_ ,1 In qo ~ (2’ 2) m
1x 2'
(It will be shown later that the strategy
qQ
is not truly optimum.)
The complete proof of the preceding solution is given in [11] and is briefly outlined here; it adheres closely to the proof given by Everett for "simple stochastic games" [9].
Consider an adaptive competitive decision
process with a single unknown payoff
an-
The total loss for
N
steps of
the process is
and the mean value of the total loss for
(5)
_ L
= iN
where
N
steps is
N k— 1 2 (v - r ) J] (1 - P?q£) k=l t=0 1 1
is defined equal to
0.
based upon the assumption that once
>
The validity of these expressions is a^
is received the players will
repeatedly use optimum strategies for the remaining known game; thus the loss will equal zero from that point on.
Equations 4 and 5 are valid only for
"memoryless" sequences of distributions, p^,
..., pN
and
q^,
..., qN .
ROSENFELD
76
Memoryless sequences are those in which
p
k
and
q
k
are independent of the
actual alternatives used by the players at steps 1, 2, • ••, k— 1.
However, the
use of Equations 4 and 5 will be restricted to cases in which one may assume with complete generality that the sequences are memoryless. Next an auxiliary matrix is constructed such that the (1, 1) is
v —
and all other entries are
minimizing player and
B
a^j + x.
qx -
A
is the
is the maximizing player, this single-step game has
a minimax solution with value denoted by and
If player
entry
y(x)
and optimum strategies
The value and minimax strategies are functions of variable
px x.
The
auxiliary matrix can be used to divide the set of all real numbers into two subsets,
S-^
and
X
S2 :
G
y(x) < x
and
x < 0, or
y(x) < x
and
x > 0;
y(x) > x
and
x > 0, or
y(x) > x
and
x< 0 .
if
St
(6) X
(The point If
G
x = 0 x
played, and if
S0
can be in both subsets.) S-^, if
g
A
N
steps of the adaptive competitive process are
uses distribution
or until the number of steps reaches
px
repeatedly until
a-^
N, then an upper bound to
is received Ljg
can be
found by substituting into Equation 5 inequalities based upon the definition of
S-^
in Equation 6.
(Equation 5 can be used despite the restriction to
memoryless sequences, since it has been demonstrated [11] that if player uses a given piecewise-stationary strategy, player
B
a memoryless strategy as he can with any more general strategy.) resultant bound to
Lx,
N x “ Ln
anci a s s i g n
>
and a s s i g n
.
tha t no
go
is u n d e t e r m i n e d .
(i)
and assign cr^,
itself
97
1:
(iii) such
but wh i c h
INFORMATION
Consider
point of P^
to
C-^.
P 1 S ^
If t h e r e
has
exists
yet been
a n d go o n
a
assigned
Step a ;
to
cr^
consistent with
to
ST, choose J-
if t h e r e
doesn ot
one
C-^ such
exist
a\, J-
such a
Step a directly.
to
Step a : (i)
We n o t e
able n u m b e r of points >
t
not
yet
that
any countable
assigned
assigned
to
to
ST 1
° ol
S^;
step
t h e r e h as
therefore,
(since
P
been only
there m u s t
a count
exist
is u n c o u n t a b l e ) .
sa -
m(pn, en ) — h, u u
under the same conditions.
PROOF. assume
that
point
Pq
The necessity of
(a1) holds, a motion for the pursuer is fixed.
(a1)
e(-)GAME
ph (0) = p0 for
F u rth er, as
and
k = 0, 1, 2,
h
is quite obvious.
is given,
Wechoose a small
and, step by step, construct a function
(10)
and (£')
p^(')GAMP
Let
and some initial positive number
h
satisfying the conditions
M(ph ( t k+1L e ( t k+1)) .
denoted by
strategy in our sense. than a positive
e(i)
(t ),
If
123
for all times
t >
t
,
pursuer corresponding to the new
The class of all motions
p(')
obtained
A, and it is not hard to verify that it is a
h-^
and
h^
are sufficiently small, say less
6, then by the second supposition of Theorem
e(T)) < e
and consequently V(p0 , eQ ) < T(A) < t + 0 < V(pr
e1 ) + e .
Hence we have proved the inequality
V(p0 , e0 ) _ V(px, P2 ) < e
for all
pairs of initial positions
< Pq , e^ >
sufficiently close, one to the other.
THEOREM 9.
Then
and
V
< p^, e-^ > which are
is uniformly continuous.
If for all initial positions
< p^, e^ >
the pursuer has at least one successful strategy and the upper value
V(p, s)
tends to zero as
to the set of final positions neighborhood of the set
F
F
< p, s >
tends
(i.e., in an appropriate
the evader can be caught in a
short time), then the game is determined and its upper value
V
(in this case
V = V) is simultaneously a minor
and major function.
PROOF. the upper value
In view of Theorem's k s 6, and 8 it is enough to verify V(p, e)
satisfies both conditions
Let us assume that eeD(eQ , h ) . e (h) = e.
D(pQ, h) x D(e^, h) and
There exists a motion
e(-)eAME
Let us take an arbitrary motion
initial values
h +
< p^, e^ >).
(o')
Of course
F
such that
and
(P1).
are disjoint and e(0) = eQ
and
p(*)GA^Pt:
(corresponding to
p(h)eD(pQ, h)
and consequently
min V(p, e) < V(p(h), e) + h < V(pn , en ) . peD(p0 ,h) ~ 0 0
that
RYLL-NARDZEWSKI
124
Hence min V(p, e) < V(p0 , h0 ) — h peD(p0 ,h)
for all
Obviously the last inequality is equivalent to Now let us fix an arbitrary point A to
as follows: p
in the time interval
(a1).
peD(pQ, h) , and define a strategy
< 0, h >
the pursuer moves from
p^
along an arbitrary segment independently from the behavior of the
evader.
At the moment
e(h)eD(eQ,h ) , then
h
some
position
the pursuer
T(A) < h +
max V(p, e). eeD(en ,h) peD(p0 ,h):
isobtained, where
A
0
max
eeD(e0 ,h)
It is
guarantees the time
Hence, by the definition of
v (Prv hn) < h +
0
< p, e(h) >
applies one of his optimal strategies.
easy to see that the described strategy
all
eeD(e0 , h ) .
V, we have for
V(p, e).
This concludes the proof. It is obvious that,
if at least one major function exists,
assumptions of Theorem 9 are satisfied.
THEOREM 10.
then both
Hence we have
If there exists some major function,
then
the game is determined.
REMARK 5.
This theorem implies for example the determinateness of
a game of pursuit and evasion of two points in a circle since the function
V
is a major function (where Vp > Vg ) .
V , Vg
P
- V
e
are maximal velocities of the players and
However we do not have an efficient way to compute the value of
this quite simple game. The following example shows that a game can be determined but its value is a discontinuous function, consequently some condition of continuity in Theorem 9 is really necessary.
A THEORY OF PURSUIT AND EVASION EXAMPLE. d(e^,e2 ) = limited
pM
< 0, 1 > —
|e -^ — e2 1
by 1). It
E, d(pr
p£ ) =
125
|Pj_ - p2 1
and
(i.e., the maximal velocities of both players are
is
easy to see that this game is determined and itsvalue
is given by the formula
V(p, e)
and
V
is not continuous.
§ 5-
GENERALIZATIONS AND PROBLEMS
Let us mention some possibilities of generalization of the above theory which are for some applications, e.g., to replace compactness by local compactness or to introduce more general payoff functions of the form T
J
cp(p (t ), e(t))dt,
0 where
t
=
min |t:
valued function. PROBLEM.
€f|
and
cp
is a given continuous real
Functionals of this type are used in optimal control theory. Let us assume that a game is determined and its value is
a continuous function.
A strategy can be called nice if it is univalent,
optimal, defined for all initial positions, all admissible motions of the enemy.
and continuous with respect to
It seems that such nice strategies of
evasion exist only in exceptional cases when the space "barriers."
E
is without
On the other hand we suspect that they exist more often for the
pursuer, e.g.,
in the pursuit of one point by another in a simply connected
domain with a sufficiently smooth boundary, under some natural restrictions on velocities.
BIBLIOGRAPHY
[1]
KELENDZERIDZE, D. L . , "Theory of optimal pursuit strategy,” Steklov Mathematical Institute, January 13, 1961.
RYLL-NARDZEWSKI
126 [2]
ZIEBA, A,, "An example in pursuit theory," Studia Math. 22 (1962), pp. 1-6.
[3]
MYCIELSKI, J., "Continuous games with perfect information," The RAND Corporation, P-2591, June, 1962.
C. Ryll-Nardzewski University of Wroclaw Wroclaw, Poland
A VARIATIONAL APPROACH TO DIFFERENTIAL GAMES Leonard D. Berkovitz § 1.
INTRODUCTION
A differential game is a two-person zero-sum game that can be described roughly as follows.
Let
t
denote time, let
be a vector in real Euclidean
n
(t, x)
or state, x(t)
space.
The position,
space, and let
(R
x = (x^,
. .., xn )
be a fixed region of
of the game is determined by
a system of first-order differential equations
(1.1)
where
|f~ = G ^ t i X ^ , z),
y = (y^,
player I and The choice of
•••, y°)
..., n,
is a vector chosen at each instant of time by
1
z = (z , ..., z y
i = 1,
s
is governed
) is a vector similarly chosen by player II. by a vector-valued
function of position and
time, Y(t, x) = (YI (t, x )j .
defined on
(R; similarly, the choice of
Y°(t, x)),
z
is governed by a vector-valued
function of position and time,
Z (t,
defined on
(R.
x) = (Z1 (t) x ) ,
The functions
strategies, and the variables
Y(t, x) y
Zs ( t ,
and
and
z
x)),
Z(t, x)
are called pure
are called strategic variables.
Each player selects his strategy from a class of permissible functions before the start of play.
The game is one of perfect information:
know the past history; they know how the game proceeds ential equations (1.1)]; and at time game.
Therefore,
t
Both players
[the system of differ
they know the state
x(t)
of the
in selecting a pure strategy, a player selects a set of 127
128
BERKOVITZ
instructions for choosing his strategic variable in all possible situations. Play begins at some initial time and position whenever
t
and the position vector
x(t)
point of a previously specified surface If
(T, x^)
starting at
(to*
xq
)
are such that
3
i-n
(ft* anc^ terminates (t, x(t))
is a.
contained in the boundary of
(ft.
denotes the point of termination of the play of the game (tQ,
xq
)* then the payoff to player I is given by
g(T, xT ) +
J
T f(t, x(t), y(t), z(t))dt,
t0 where
g
is a real-valued function on
(t, x, y, z)
3, f is a real-valued function on
space, y(t) = Y(t, x(t)), and
of player I is to select a strategy of player II is to select a strategy
z(t) = Z(t, x(t)).
Y(t, x)
The objective
that maximizes the payoff; that
Z(t, x)
that minimizes the payoff.
The study of differential games was initiated by Rufus Isaacs [6]. Isaac's treatment of the problem was quite formal and heuristic. very little additional work has been done on the problem.
Nevertheless,
Fleming [4],
[5],
and Scarf [7] have considered discrete approximations to certain types of differential games.
In [1], Fleming and the present author studied a special
class of differential games in the plane by means of techniques and results from the calculus of variations. In this paper, we shall study a much wider class of differential games than those considered in [1], again using techniques and results from the calculus of variations.
The present investigation, however,
complete, even for the special case corresponding to [1]. describe the class of games to be studied.
is more
First, we shall
Necessary conditions that must
hold along a path resulting from the employment of optimal pure strategies by the two players will then be deduced for the present class of games.
This
will be done by relating the problem of determining these necessary conditions to a problem of Bolza with differential inequalities as added side conditions. The theory of such Bolza problems will then be used to obtain the desired necessary conditions.
The continuity and differentiability properties of the
value will be studied next, and we shall show that the value satisfies an analogue of the Hamilton-Jacobi equation. shall develop a sufficiency theory that,
In the last part of the paper, we in principle, enables us to construct
DIFFERENTIAL GAMES optimal pure strategies. carried out.
In some
examples,
Some of our results
129
this construction can actually be
were obtained by Isaacs [6] in
a formal
manner or under more restrictive assumptions. We conclude this introductory section by listing certain definitions and conventions that we shall use throughout the paper. notation will generally be used. single letters.
Vector matrix
Vectors and matrices will be denoted by
Superscripts will be used to denote the components of a
vector; subscripts will be used to distinguish vectors.
Vectors will be
written as matrices consisting of either one row or one column. We shall not use a transpose symbol to distinguish between the two usages, as it will be clear from the context how the vector, is to be considered. of two n-dimensional vectors
X
and
Thus, the product
G, say, will be written as
^G.
All
scalars that occur will be real and all vectors will have real components. A vector will be called positive if each of its components is positive. Negative, nonpositive and nonnegative vectors are defined similarly.
The
length
of a vector
x
will be denoted by
llxll .
Let
X (t,x,y, z) = (x (t,x, y, z ), •••} X (t,x.,y,z))
be a vector-valued function defined and differentiable on a region of (t, x, y ,
z)
space.
If
z
is an s-dimensional vector, we can form a matrix
of partial derivatives in which the (i,j)-th element is
—3X— 1 dXJ The symbol
Xz
1• = ,1,
. . ., m,and
will denote this matrix.
,
, j. = 1, ...,
Note that when
reduces to the usual notation for a partial derivative. and
Xy
will have
will
be denoted
similar meanings.
by det
M.
Thedeterminant
s.
m = 1, s = 1, this The symbols
Xx
of a square matrix
M
130
BERKOVITZ The term region will mean, as usual, an open connected set.
The
closure of a region 3D will be denoted by 3D, and
3D will be called a (k) closed region. A real-valued function will be said to be of class C' 3D if it is
on
those of order
k
3) and all of its derivatives up to and including
have continuous extensions to 3D.
will be said to be of class on
3D.
on
on
A vector-valued function
3D if each of its components is
A region will be said to have a piecewise smooth boundary if its
boundary consists of a finite number of manifolds with boundary. The letter
t
will denote time, and the operator
(d/dt)
will be
denoted by a prime.
§ 2.
2.1
The Functions Let x
vector,
and let
(t, x, y, z) into
and
g
of
(t,x)
space and a
We assume that
space.
g
f(t, x, y, z)
with range contained in Euclidean §.
bounded region
§
of
is contained in the projection of
G(t,x,y,z) = (G1 (t,x,y,z),
on
be an s-dimensional
As we indicated in Section 1, we shall be concerned
with a real-valued function
of class
let y
be an s-dimensional vector. We shall be concerned with
space.
(t, x)
G
an n-dimensional vector,
z
a bounded region
§
f
be
FORMULATION OF THE GAME
n
and a vector-valued function
..., Gn (t,x,y,z))
space.
We assume that
f
and
G
are
We may write the system (1.1) in vector notation as
(2.1)
x 1 = G(t,x,y,z),
where the prime denotes differentiation with respect to time. 2.2
The Constraints We now discuss functions
of strategic variable
K(t, x, z)
z, and functions
K(t, x, y)
that will constrain the
choice of strategic variable
y.
into
K(t, x, z) be a vector-valued
(t, x, z)
space.
Let
Let
that will constrain the choice
denote the projection of function
§ of class
DIFFERENTIAL GAMES C^2 ^
§>(Z K
on
131
having range on p-dimensional space and satisfying the
following constraint conditions:
(2.2)
(i)
The set of points that
(ii)
If
(t, x, z)
K(t, x, z) > 0
in
is nonvoid.
p > s, then at each
(t, x, z)
at most
s
vanish.
The matrix with elements
of the components of
formed from those components vanish at
(t, x, z)
such
K1
§>,
in K
of
can
K
that
has maximum rank at
(t, x, z).
A third constraint condition will be stated presently. Let containing
w
be a naturally ordered subset of the integers
at most
s
elements.
For each such
w
1,
. .., p
consider the system of
equations
(2-3)
K l"(t, x, z) = 0,
where the symbol of
K
having indices that belong to
the natural order. holds.
denotes a vector whose components are those components
Let
S^2^
ws and the order of the components
denote the subset of
It follows from (2.2) (ii) that
S^2^
is
on which (2.3)
is either the null set or a
differentiable manifold, and the solutions of (2.3) can be used to obtain a system of local coordinates for
S^2 ^*
We can now state our third constraint
condition:
(iii)
Each manifold
S^2^
can be represented
by a finite number of overlapping coordinate systems obtained by using solutions of (2.3) that always include
(t, x)
in the set of
independent variables.
These solutions of (2.3) will be referred to as the coordinate solutions.
132
BERKOVITZ The constraints on the choice of
function
K(t, x, y)
of class
y
are furnished by vector-valued
on
having range in a p-dimensional
space, and satisfying (2.2) and (2.3) with appropriate changes in notation. An important special case, which also serves to illustrate (2.3), is that of
separable constraints.
not necessarily disjoint, of the set on j
in
g
for
S2 •If
k
i
in
x) > B^(t, x)
that
(t, x, z) is in
hold, be nonvoid.
on
S^, and let
g.
and S2
1, ..., s. B^(t, x)
is an integer in both
A^(t,
Let
S-^
For each
Let
A x (t, x)
be of class on
S2 , we suppose
(t, x)
in
g
for
that
g, let the set of
z
such
and such that the inequalities
A X (t, x) — z1 > 0,
i in
S-^,
7? — BJ (t, x) > 0,
j in
S2 ,
Then we can form a vector-valued function
that satisfies
(2.2) and (2.3) by taking the functions
ZJ
as the components of
_ B^(t, x)
be two subsets,
be of class
and
(2-2) and
K
K(t, x, z)
A 1 (t, x) — z1
and
and, if necessary, relabeling the
superscripts. 2-3
Terminal Manifolds For each
i = 1, ..., a ,
let
i £L
be an n-dimensional manifold of
(2 )
class
Cv
that lies in
(2.4)
g
and that is given parametrically by equations
t = t^a)
where
cr = (a^,
..., a11)
x = x t (a),
ranges over an open cube
CKL
in n-dimensional r
space.
We select a connected submanifold
CL
of each
3^.
Let
a
u
3 =
i=l We shall call belong to
3
81
g(t, x)
g(T, xT ) shall call
the terminal surface of
will be denoted by
Let Let
3
3.. 1 the game.
be a subregion of
g
such that
3
be a real-valued function of class
is therefore defined on g(T, x^)
Points
(t, x)
that
(T, x,p) .
3
and
the terminal payoff
is of class function.
is contained in on
8]_*
8-^*
The function
on each
3^
We
DIFFERENTIAL GAMES
133
3^
We remark that the assumption that all of by parameters
is made to simplify the subsequent exposition. (2 ) The essential assumption is that £L is a C K manifold.
2.4
cr
can be coordinatized
in
Strategies A notion that will be used in our discussion of strategies and
other subsequent work is that of a decomposition of a region.
3D-^, . .., 3Da
collection of subregions
(i)
Each
3D^ i = 1, ..., ct, is connected and has a piecewise-smooth (ii)
3D^ n 3Dj = 0
valued function defined on
if 3D
Let
(R
on3D^.
3D
3
A real on
3L.
i = 1,
...,
(R
The region
A vector-valued function will be said
(R contained in
on &
(R.
a, the region
(R^
will be the region of
anc* such that Further, assume §,
denote the class of functions
(R and satisfy the following conditions:
(t,
the projection of §
lies in
For every
K(t, x, Y(t, x)) > 0 ;
the y-constraints.
Similarly,
(R
let
Z
(t, x)
values
lie in an s-dimensional space.
in (R, the point
S
i-s
in
into
lies in
We assume that Y
in
associated with it a decomposition of
C^2 ^
y = Y(t, x)
(R, the point (t, x, y)
and satisfy the following conditions:
(t, x, Z(t, x))
Since a function
piecewise
denote the class of functions
on
K(t, x, Z(t, x)) > 0.
and
space,
that is, the functional values satisfy
are piecewise z = Z(t, x)
space in which
(i) The values
(ii)
x, Y(t, x))
(t, x)
Y that are
lie in an s-dimensional space.
and satisfies
and
is always on the same
(R c
Note that since
3D.
(R is compact.
it follows that
y
3D
the function agrees
can be imbedded in an n-dimensional manifold that separates
Let on
3D^
forms a part of the boundary of
the play of the game takes place. bounded,
3)^*
if each component is piecewise
be a region with closure
that, for any given side of
such that oneach —
Cv on
the terminal surface
3
3D
(k)
with a function that is to be piecewise
i ^ j, and (iii) 3D =
will be said to be piecewise
if there is a decomposition of
that
3D will be said to
of a region
3D whenever the following conditions hold:
constitute a decomposition of
boundary,
A finite
(ii)
(i)
For every
Z
that
The (t, x)
and satisfies and
Z
is piecewise
are nonvoid. on
(R, there is
(R, and the same is true of a function
134 Z
BERKOVITZ in
Z.
Hence a pair of functions
(Y, Z)
with
also has associated with it a decomposition of
Y
in
^
and
(R, say (R-^,
Z
Z
in
(R^. It
follows from standard existence theorems for ordinary differential equations and the hypotheses concerning the functions to a given point
(tQ,
xq
)j interior to some
G, Y, and
Z, that corresponding
(R^, there exists a unique
solution
x(t) = x(t; tQ , xQ )
(2.5)
of the system of differential equations
(2 .6 )
x' = G(t, x, Y(t, x), Z(t, x)),
defined on some interval about
(2.7)
and satisfying the initial condition
x(t0 ) = x(tQ ; tQ, xQ ) = xQ .
What we shall need, however, (i)
tg
x(t; tQ, X q )
other regions
(R^
is the assurance that either
can be continued across the boundary of so as to reach
point on the boundary of
(R^
3, or
(ii)
x(t; tQ, X q )
that is also a point of
game, we
need to be assured that a play starting at
Further,
if
of (R^ and
(tQ, X q ) (R^
is both an interior point of
for some pair of indices
exist for solutions of
(R^
3.
and through
extends to a
In terms of the
(tQ, X q )will
(Rand a
terminate.
boundary point
i, j, then several possibilities
(2.6) satisfying the initial conditions (2.7).
Thus,
to ensure that play can take place, we need to impose restrictions on the functions
Y
and
Z
chosen as strategies by the players.
The restrictions
presently to be made are imposed partly for this purpose, and partly to enable us to carry out our analysis. We define a regular decomposition of a region
(R
to be a
decomposition in which the constituent subregions can be designated
DIFFERENTIAL GAMES
135
in such a way (see Fig. 1) that the following conditions are satisfied:
(i)
The regions
i = 1,
(R^, defined for each
a
by the formula
( h
\
constitute a decomposition of (ii)
same side of (iii)
3^, and
(Rij n 3i= 0
a , (R. . H 3 ^
whenever
i = 1,
For each
always lies on the
(R^ fl 3k = 0 whenever i / k.
i = 1, . . . ,
For each
_
(iv)
a , (R^
For each i = 1,
(R.
0,
and
j ^ j^. a, and j = 1, ..., j ^— 1,
...,
the set
is a connected and oriented manifold of dimension n
and class
We suppose that ^ - jj
can
described by equations
(2-8)
t = £^(0)
where
cr = (cr'*’,
x = x^cr),
crn )
ranges over a cube
in Euclidean n-space. (v)
Each manifold 971-jj
divides
(R^
into two disjoint
regions such that each region lies entirely on one side of 971. • • ij i = 1, a, (vi)
For each subset a,
1,
Furthermore, 971. . 0 971., = 0 ij and j, k = 1, j i - 1. i^,
..., i^
the set
91.
.
n (R.
of the integers . , defined by the ik
ir
formula
91.
ir ...,ik
= (& .
for
i2
n ... n 0
if
Z*1 ^ ,
= 0
if
B1 (t, x) < Z*x (t, x) < A 1 (t, x),
< 0
if
Z ^(t, x) = A^(t, x ) .
statements involving neither
(t, x)
If
i
i
deleted.
F ^ = 0.
belongs to
S-^
and
If
i
is in
Similarly,
if
S2 , then at every
interior to some
if
Y i (t, x) = A i (t, x ) ,
, = 0
if
B X (t, x) < Y*x (t, x) < A 1 (t, x
< 0
if
Y #i (t, x) = B ^ t ,
is not
modifications
If
S^(S2 ), then (4 .13) holds with
0
" > Fyi
x) = B1 (t, x),
A 1 (B1 )
nor S2 , then
i(i = 1, . .., s)
(4.14)
S2 , then at every
interior to some
does not belong to
point
and
If
in both S-^and
K; if
component of
K.
i
S2 , then the appropriate
hold, as in the case of
belongs to
component of
x).
Sp
let
j^(i)
belongs toS2 , let
Suppose that
i
F . z-1-
denote the corresponding j2 (i)
belongs to
denote the corresponding
S^ and
and the definition of separable constraints, we get
S2 .
Then
from (4.4)
_ 1
DIFFERENTIAL GAMES
157
P i ; Ji(i) F . = 2 LLJ KJ i = - L i + M 2 j=l The conclusion (4.13) now follows from (4-5)* since
A
i
(4-6)* and the observation that,
i > B , one and only one ofthe three conditions
B^ < Z ^ < A^
can hold at a point.
Z
*i
The statement following
i = A ,
*i i Z = B ,
(4.13) is a
of (4.5), (4.6), and the observation that if ibelongs only jpW JiCi) S-^(S2 ), then i~i =0(d =0). Similar arguments yield (4.14).
consequence
to
Another special case in which a simplification of Theorem 1 can be effected is that in which the constraints are independent of the state variable
x.
COROLLARY 2-
If K
then at every
is independent
(t, x)
of
x, i.e., K =K(t, z),
interior to some
(4.15)
F Z* = 0. z x If
K
is independent of
every
(t, x)interior
x, i.e., K = K(t, y), then at to some
(4.16)
FyY* = 0.
If both
K and
_
K
are independent
(4.17)
of
x, thenalong
* E ,
M t ) = - F x. Equation (4-15) follows from (4.10) and the observation that since
K
is independent of
similarly.
x, we have
Kx = 0.
Equation (4.16) is established
Equation (4-17) follows from (4.3),
(4.15), and (4-17).
If the constraints are separable and the functions are all constants, or depend at most on
A 1, B 1, A 1, B 1
t, then the conclusions of both
corollaries apply. 4.4
Further Necessary Conditions The next necessary condition is most easily stated in terms of a
game that we now describe. * Let E be an optimal path and let in Theorem 2.
At every point
construct a game
^(t, x (t))
Q=(t,
x(t))
^(t) of
be the function described E
in the following manner.
with
t ^ t^,
we
The pure strategies
158
BERKOVITZ
for player I consist of (a) some
Y
in 2/^
all vectors
that is continuous at
y = Y+ (t, x (t))
for some
Y
in
y
Q, and (b)
vectors
z
for some
Z
such that
discontinuous at
in
defined
in (4.1).
that we
take the payoff to be
THEOREM 3.
t = t^
•X-
for some
Z
y
such that The pure z =
Q, and (b)
in % ^
all
that is
F(t, x (t), y, z, *-(t)), where
F(t, x (t), y , z ,
F
*5 asbefore,
is
except
^+ (t)).
(t, x (t)), with
E , the game
for
Q.
such that
at Q, we can construct
At every point
of an optimal path
z
that is continuous at
The payoff is If
all vectors
all vectors
z = Z+ (t, x (t))
Q.
y = Y(t, x (t))
that is discontinuous at
strategies for player II consist of (a) Z(t, x (t))
such that
t ^ t^,
^(t, x (t))
-X-
F(t, x (t), y (t), z (t), X(t)), where
y (t)
has value and
z (t)
are given by (2.15). An optimal pure strategy for player * I is y (t) and an optimal pure strategy for player II is
z (t) .
At
t = t^,
^(t, x (t))
has value
F(t, x (t), y (t)+, z (t)+, X+ (t)); an optimal pure * + strategy for player I is y (t) , and an optimal pure strategy for player II is z (t) . This theorem follows from Condition II of Theorem
1when that * Z in the class
theorem is applied to the problems of maximizing against ^ ^
and minimizing against
Y
in the class
The following theorem is a consequence
of Condition III,
applied to
the preceding maximization and minimization problems.
THEOREM 4.
Let
be a point of formed from
E E
K
be
an optimal path, and let
with
t ^ t^j .
Let
by taking those components of
vanish at that point.
Let
e = (e^,
..., em )
solution vector of the linear system e((F + uK)zz)e > 0
at this point.
denote the vector formed from of
K
K
that vanish at this point.
(t, x
K denote K
that
be a nonzero
Kze = 0Similarly,
Then let
e(F + u K ) ^ ) e < 0
K
by taking these components Let
e
be an
s-dimensional nonzero solution vector of the system Then
(t))
the vector
at this point.
K e = 0.
DIFFERENTIAL GAMES § 5.
5«1
The Function
159
THE VALUE W(t, x)
A (t , x )
The principal purpose of this section is to study the differentia bility properties of the value equation that purpose,
W
it is
multiplier
W
and to deduce a partial differential
satisfies in its regions of differentiability.
convenient to introduce a function
A,
For this
A(t, x), related to the
and to derive some of its properties.
(R^, where (R ^
and consider a subregion
Sec. 2.4) of regular decomposition.
* * (Y , Z )
(R associated with
Consider the regular decomposition of
is as in (i) of the definition (see
In (R., we now consider
(R.. .
To
Ji simplify notation, we set
= m.
Through each point of (R^m
there passes a unique optimal path
terminating at
3^.
terminal point
of precisely one optimal path.
terminating at
(T,
Conversely, each point
xt)
(5.1)
= (t^(cr), x^(cr))
(t^(cr), x^(cr))
of
3^ is
the
Thus an optimal path in (R^m
can be written as
x*(t, a) = x*(t, ti (a), x i (d)) .
Since
x (t, cr)
it follows that
x
is the
(t, cr)
solution of (2.14) with
is of class
space defined by the requirements -* (2 ) Moreover, x (t, cr) is in
C ^
x(t^(cr)) = x^(cr),
on the region cU^m
cr e 3C^, and
of
(t, cr)-
t^ m - i ^ ) < t < t^(tf).
~
The argument to establish these * * the continuity properties of G, Y , Z ,(ii) extensions
statements uses (i) * * of Y^m and Z^m to functions that are of class (Rim* 3 ^
and
311^
xi (cr) are of class
in its interior, C^^,
(iii)
(2 )
C v ' in a region containing
the assumption that
ti (cr)
and
and (iv) standard theorems concerning the dependence of
solutions of differential equations on initial conditions. We now show that for (t, cr)
such that
(5.2)
Let the vector
cr
in
3C^
(t, cr) v and
det
* xt
in *11. , where lm
t^ ^ ^ f 07)