Difference between revisions of "Minimax principle"
Ulf Rehmann (talk | contribs) m (MR/ZBL numbers added) |
(TeX) |
||
| Line 1: | Line 1: | ||
| − | An optimality principle for a [[Two-person zero-sum game|two-person zero-sum game]], expressing the tendency of each player to obtain the largest sure pay-off. The minimax principle holds in such a game | + | {{TEX|done}} |
| + | An optimality principle for a [[Two-person zero-sum game|two-person zero-sum game]], expressing the tendency of each player to obtain the largest sure pay-off. The minimax principle holds in such a game $\Gamma=\langle A,B,H\rangle$ if the equality | ||
| − | + | $$v=\max_{a\in A}\min_{b\in B}H(a,b)=\min_{b\in B}\max_{a\in A}H(a,b)\tag{*}$$ | |
| − | holds, that is, if there are a value of the game, equal to | + | holds, that is, if there are a value of the game, equal to $v$, and optimal strategies for both players. |
| − | For a [[Matrix game|matrix game]] and for certain classes of infinite two-person zero-sum games (see [[Infinite game|Infinite game]]) the minimax principle holds if mixed strategies are used. It is known that | + | For a [[Matrix game|matrix game]] and for certain classes of infinite two-person zero-sum games (see [[Infinite game|Infinite game]]) the minimax principle holds if mixed strategies are used. It is known that \ref{*} is equivalent to the inequalities (see [[Saddle point in game theory|Saddle point in game theory]]): |
| − | + | $$H(a,b^*)\leq H(a^*,b^*)\leq H(a^*,b)$$ | |
| − | for all | + | for all $a\in A$, $b\in B$, where $a^*$ and $b^*$ are the strategies on which the external extrema in \ref{*} are attained. Thus, the minimax principle expresses mathematically the intuitive conception of stability, since it is not profitable for either player to deviate from his optimal strategy $a^*$ (respectively, $b^*$). At the same time the minimax principle guarantees to player I (II) a gain (loss) of not less (not more) than the value of the game. An axiomatic characterization of the minimax principle for matrix games has been given (see [[#References|[1]]]). |
====References==== | ====References==== | ||
Revision as of 12:20, 14 August 2014
An optimality principle for a two-person zero-sum game, expressing the tendency of each player to obtain the largest sure pay-off. The minimax principle holds in such a game $\Gamma=\langle A,B,H\rangle$ if the equality
$$v=\max_{a\in A}\min_{b\in B}H(a,b)=\min_{b\in B}\max_{a\in A}H(a,b)\tag{*}$$
holds, that is, if there are a value of the game, equal to $v$, and optimal strategies for both players.
For a matrix game and for certain classes of infinite two-person zero-sum games (see Infinite game) the minimax principle holds if mixed strategies are used. It is known that \ref{*} is equivalent to the inequalities (see Saddle point in game theory):
$$H(a,b^*)\leq H(a^*,b^*)\leq H(a^*,b)$$
for all $a\in A$, $b\in B$, where $a^*$ and $b^*$ are the strategies on which the external extrema in \ref{*} are attained. Thus, the minimax principle expresses mathematically the intuitive conception of stability, since it is not profitable for either player to deviate from his optimal strategy $a^*$ (respectively, $b^*$). At the same time the minimax principle guarantees to player I (II) a gain (loss) of not less (not more) than the value of the game. An axiomatic characterization of the minimax principle for matrix games has been given (see [1]).
References
| [1] | E. Vilkas, "Axiomatic definition of the value of a matrix game" Theory Probabl. Appl. , 8 (1963) pp. 304–307 Teor. Veroyatnost. i Primenen. , 8 : 3 (1963) pp. 324–327 MR0154750 Zbl 0279.90044 |
Comments
The fact that the minimax principle holds if mixed strategies are allowed is called the minimax theorem; it is due to J. von Neumann.
References
| [a1] | J. von Neumann, O. Morgenstern, "Theory of games and economic behavior" , Princeton Univ. Press (1947) MR21298 Zbl 1112.91002 Zbl 1109.91001 Zbl 0452.90092 Zbl 0205.23401 Zbl 0097.14804 Zbl 0053.09303 Zbl 0063.05930 |
Minimax principle. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Minimax_principle&oldid=32909