Distributed Convergence to Nash Equilibria in Two-Network Zero-Sum Games

Abstract

This paper considers a class of strategic scenarios in which two networks of agents have opposing objectives with regards to the optimization of a common objective function. In the resulting zero-sum game, individual agents collaborate with neighbors in their respective network and have only partial knowledge of the state of the agents in the other network. For the case when the interaction topology of each network is undirected, we synthesize a distributed saddle-point strategy and establish its convergence to the Nash equilibrium for the class of strictly concave-convex and locally Lipschitz objective functions. We also show that this dynamics does not converge in general if the topologies are directed. This justifies the introduction, in the directed case, of a generalization of this distributed dynamics which we show converges to the Nash equilibrium for the class of strictly concave-convex differentiable functions with globally Lipschitz gradients. The technical approach combines tools from algebraic graph theory, nonsmooth analysis, set-valued dynamical systems, and game theory.

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Document Details

Document Type
Technical Report
Publication Date
Feb 17, 2013
Accession Number
ADA579430

Entities

People

  • Bahman Gharesifard
  • J. Cortes

Organizations

  • University of California, San Diego

Tags

Communities of Interest

  • Energy and Power Technologies

DTIC Thesaurus Topics

  • Algorithms
  • Applied Mathematics
  • Communication Channels
  • Control Systems
  • Control Systems Engineering
  • Convergence
  • Dynamics
  • Eigenvalues
  • Equations
  • Game Theory
  • Graph Theory
  • Mathematics
  • Optimization
  • Sensor Networks
  • Signal Processing
  • Topology
  • United States

Fields of Study

  • Economics

Readers

  • Game Theory.
  • Graph Algorithms and Convex Optimization.
  • Mathematical Modeling and Probability Theory.