Dynamics at the boundary of game theory and distributed computing

Aaron D. Jaggard; Neil Lutz; Michael Schapira; Rebecca N. Wright

doi:10.1145/3107182

Dynamics at the boundary of game theory and distributed computing

Aaron D. Jaggard, Neil Lutz, Michael Schapira, Rebecca N. Wright

The Rachel and Selim Benin School of Engineering and Computer Science

The Hebrew University of Jerusalem

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

Abstract

We use ideas from distributed computing and game theory to study dynamic and decentralized environments in which computational nodes, or decision makers, interact strategically and with limited information. In such environments, which arise in many real-world settings, the participants act as both economic and computational entities. We exhibit a general non-convergence result for a broad class of dynamics in asynchronous settings. We consider implications of our result across a wide variety of interesting and timely applications: game dynamics, circuit design, social networks, Internet routing, and congestion control. We also study the computational and communication complexity of testing the convergence of asynchronous dynamics. Our work opens a new avenue for research at the intersection of distributed computing and game theory.

Original language	English
Article number	15
Journal	ACM Transactions on Economics and Computation
Volume	5
Issue number	3
DOIs	https://doi.org/10.1145/3107182
State	Published - Aug 2017

Keywords

Adaptive heuristics
Game dynamics
Self stabilization

All Science Journal Classification (ASJC) codes

Computer Science (miscellaneous)
Statistics and Probability
Economics and Econometrics
Marketing
Computational Mathematics

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10.1145/3107182

Cite this

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title = "Dynamics at the boundary of game theory and distributed computing",

abstract = "We use ideas from distributed computing and game theory to study dynamic and decentralized environments in which computational nodes, or decision makers, interact strategically and with limited information. In such environments, which arise in many real-world settings, the participants act as both economic and computational entities. We exhibit a general non-convergence result for a broad class of dynamics in asynchronous settings. We consider implications of our result across a wide variety of interesting and timely applications: game dynamics, circuit design, social networks, Internet routing, and congestion control. We also study the computational and communication complexity of testing the convergence of asynchronous dynamics. Our work opens a new avenue for research at the intersection of distributed computing and game theory.",

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AU - Jaggard, Aaron D.

AU - Lutz, Neil

AU - Schapira, Michael

AU - Wright, Rebecca N.

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N2 - We use ideas from distributed computing and game theory to study dynamic and decentralized environments in which computational nodes, or decision makers, interact strategically and with limited information. In such environments, which arise in many real-world settings, the participants act as both economic and computational entities. We exhibit a general non-convergence result for a broad class of dynamics in asynchronous settings. We consider implications of our result across a wide variety of interesting and timely applications: game dynamics, circuit design, social networks, Internet routing, and congestion control. We also study the computational and communication complexity of testing the convergence of asynchronous dynamics. Our work opens a new avenue for research at the intersection of distributed computing and game theory.

AB - We use ideas from distributed computing and game theory to study dynamic and decentralized environments in which computational nodes, or decision makers, interact strategically and with limited information. In such environments, which arise in many real-world settings, the participants act as both economic and computational entities. We exhibit a general non-convergence result for a broad class of dynamics in asynchronous settings. We consider implications of our result across a wide variety of interesting and timely applications: game dynamics, circuit design, social networks, Internet routing, and congestion control. We also study the computational and communication complexity of testing the convergence of asynchronous dynamics. Our work opens a new avenue for research at the intersection of distributed computing and game theory.

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KW - Self stabilization

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JF - ACM Transactions on Economics and Computation

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ER -

Dynamics at the boundary of game theory and distributed computing

Abstract

Keywords

All Science Journal Classification (ASJC) codes

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