Sparse binary zero-sum games

David Auger; Jianlin Liu; Sylkvie Ruette; David Saint-Pierre; Oliver Teytaud

Sparse binary zero-sum games

David Auger, Jianlin Liu, Sylkvie Ruette, David Saint-Pierre, Oliver Teytaud

Proceedings of the Sixth Asian Conference on Machine Learning, PMLR 39:173-188, 2015.

Abstract

Solving zero-sum matrix games is polynomial, because it boils down to linear programming. The approximate solving is sublinear by randomized algorithms on machines with random access memory. Algorithms working separately and independently on columns and rows have been proposed, with the same performance; these versions are compliant with matrix games with stochastic reward. [1] has proposed a new version, empirically performing better on sparse problems, i.e. cases in which the Nash equilibrium has small support. In this paper, we propose a variant, similar to their work, also dedicated to sparse problems, with provably better bounds than existing methods. We then experiment the method on a card game.

Cite this Paper

BibTeX


@InProceedings{pmlr-v39-auger14,
  title = 	 {Sparse binary zero-sum games},
  author = 	 {Auger, David and Liu, Jianlin and Ruette, Sylkvie and Saint-Pierre, David and Teytaud, Oliver},
  booktitle = 	 {Proceedings of the Sixth Asian Conference on Machine Learning},
  pages = 	 {173--188},
  year = 	 {2015},
  editor = 	 {Phung, Dinh and Li, Hang},
  volume = 	 {39},
  series = 	 {Proceedings of Machine Learning Research},
  address = 	 {Nha Trang City, Vietnam},
  month = 	 {26--28 Nov},
  publisher =    {PMLR},
  pdf = 	 {http://proceedings.mlr.press/v39/auger14.pdf},
  url = 	 {https://proceedings.mlr.press/v39/auger14.html},
  abstract = 	 {Solving zero-sum matrix games is polynomial, because it boils down to linear programming. The approximate solving is sublinear by randomized algorithms on machines with random access memory. Algorithms working separately and independently on columns and rows have been proposed, with the same performance; these versions are compliant with matrix games with stochastic reward. [1] has proposed a new version, empirically performing better on sparse problems, i.e. cases in which the Nash equilibrium has small support. In this paper, we propose a variant, similar to their work, also dedicated to sparse problems, with provably better bounds than existing methods. We then experiment the method on a card game.}
}

Endnote

%0 Conference Paper
%T Sparse binary zero-sum games
%A David Auger
%A Jianlin Liu
%A Sylkvie Ruette
%A David Saint-Pierre
%A Oliver Teytaud
%B Proceedings of the Sixth Asian Conference on Machine Learning
%C Proceedings of Machine Learning Research
%D 2015
%E Dinh Phung
%E Hang Li	
%F pmlr-v39-auger14
%I PMLR
%P 173--188
%U https://proceedings.mlr.press/v39/auger14.html
%V 39
%X Solving zero-sum matrix games is polynomial, because it boils down to linear programming. The approximate solving is sublinear by randomized algorithms on machines with random access memory. Algorithms working separately and independently on columns and rows have been proposed, with the same performance; these versions are compliant with matrix games with stochastic reward. [1] has proposed a new version, empirically performing better on sparse problems, i.e. cases in which the Nash equilibrium has small support. In this paper, we propose a variant, similar to their work, also dedicated to sparse problems, with provably better bounds than existing methods. We then experiment the method on a card game.

RIS


TY  - CPAPER
TI  - Sparse binary zero-sum games
AU  - David Auger
AU  - Jianlin Liu
AU  - Sylkvie Ruette
AU  - David Saint-Pierre
AU  - Oliver Teytaud
BT  - Proceedings of the Sixth Asian Conference on Machine Learning
DA  - 2015/02/16
ED  - Dinh Phung
ED  - Hang Li	
ID  - pmlr-v39-auger14
PB  - PMLR
DP  - Proceedings of Machine Learning Research
VL  - 39
SP  - 173
EP  - 188
L1  - http://proceedings.mlr.press/v39/auger14.pdf
UR  - https://proceedings.mlr.press/v39/auger14.html
AB  - Solving zero-sum matrix games is polynomial, because it boils down to linear programming. The approximate solving is sublinear by randomized algorithms on machines with random access memory. Algorithms working separately and independently on columns and rows have been proposed, with the same performance; these versions are compliant with matrix games with stochastic reward. [1] has proposed a new version, empirically performing better on sparse problems, i.e. cases in which the Nash equilibrium has small support. In this paper, we propose a variant, similar to their work, also dedicated to sparse problems, with provably better bounds than existing methods. We then experiment the method on a card game.
ER  -

APA


Auger, D., Liu, J., Ruette, S., Saint-Pierre, D. & Teytaud, O.. (2015). Sparse binary zero-sum games. Proceedings of the Sixth Asian Conference on Machine Learning, in Proceedings of Machine Learning Research 39:173-188 Available from https://proceedings.mlr.press/v39/auger14.html.

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