Cournot-nash equilibrium and optimal transport in a dynamic setting

Beatrice Acciaio; Julio Backhoff Veraguas; Junchao Jia

doi:10.1137/20M1321462

Cournot-nash equilibrium and optimal transport in a dynamic setting

Beatrice Acciaio, Julio Backhoff Veraguas, Junchao Jia

Research output: Contribution to journal › Article › Academic › peer-review

9 Citations (Scopus)

Abstract

We consider a large population dynamic game in discrete time. The peculiarity of the game is that players are characterized by time-evolving types, and so reasonably their actions should not anticipate the future values of their types. When interactions between players are of mean field kind, we relate Nash equilibria for such games to an asymptotic notion of dynamic Cournot-Nash equilibria. Inspired by the works of Blanchet and Carlier for the static situation, we interpret dynamic Cournot-Nash equilibria in the light of causal optimal transport theory. Further specializing to games of potential type, we establish existence, uniqueness, and characterization of equilibria. Moreover we develop, for the first time, a numerical scheme for causal optimal transport, which is then leveraged in order to compute dynamic Cournot-Nash equilibria. This is illustrated in a detailed case study of a congestion game.

Original language	English
Pages (from-to)	2273-2300
Number of pages	28
Journal	SIAM journal on control and optimization
Volume	59
Issue number	3
DOIs	https://doi.org/10.1137/20M1321462
Publication status	Published - 2021

Keywords

n/a OA procedure
Congestion
Mean field games
Nash equilibrium
Optimal transport
Potential games
Causal transport

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10.1137/20M1321462

Cite this

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title = "Cournot-nash equilibrium and optimal transport in a dynamic setting",

abstract = "We consider a large population dynamic game in discrete time. The peculiarity of the game is that players are characterized by time-evolving types, and so reasonably their actions should not anticipate the future values of their types. When interactions between players are of mean field kind, we relate Nash equilibria for such games to an asymptotic notion of dynamic Cournot-Nash equilibria. Inspired by the works of Blanchet and Carlier for the static situation, we interpret dynamic Cournot-Nash equilibria in the light of causal optimal transport theory. Further specializing to games of potential type, we establish existence, uniqueness, and characterization of equilibria. Moreover we develop, for the first time, a numerical scheme for causal optimal transport, which is then leveraged in order to compute dynamic Cournot-Nash equilibria. This is illustrated in a detailed case study of a congestion game.",

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AU - Acciaio, Beatrice

AU - Veraguas, Julio Backhoff

AU - Jia, Junchao

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N2 - We consider a large population dynamic game in discrete time. The peculiarity of the game is that players are characterized by time-evolving types, and so reasonably their actions should not anticipate the future values of their types. When interactions between players are of mean field kind, we relate Nash equilibria for such games to an asymptotic notion of dynamic Cournot-Nash equilibria. Inspired by the works of Blanchet and Carlier for the static situation, we interpret dynamic Cournot-Nash equilibria in the light of causal optimal transport theory. Further specializing to games of potential type, we establish existence, uniqueness, and characterization of equilibria. Moreover we develop, for the first time, a numerical scheme for causal optimal transport, which is then leveraged in order to compute dynamic Cournot-Nash equilibria. This is illustrated in a detailed case study of a congestion game.

AB - We consider a large population dynamic game in discrete time. The peculiarity of the game is that players are characterized by time-evolving types, and so reasonably their actions should not anticipate the future values of their types. When interactions between players are of mean field kind, we relate Nash equilibria for such games to an asymptotic notion of dynamic Cournot-Nash equilibria. Inspired by the works of Blanchet and Carlier for the static situation, we interpret dynamic Cournot-Nash equilibria in the light of causal optimal transport theory. Further specializing to games of potential type, we establish existence, uniqueness, and characterization of equilibria. Moreover we develop, for the first time, a numerical scheme for causal optimal transport, which is then leveraged in order to compute dynamic Cournot-Nash equilibria. This is illustrated in a detailed case study of a congestion game.

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KW - Nash equilibrium

KW - Optimal transport

KW - Potential games

KW - Causal transport

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Cournot-nash equilibrium and optimal transport in a dynamic setting

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