Best-response dynamics, playing sequences, and convergence to equilibrium in random games

Torsten Heinrich; Yoojin Jang; Luca Mungo; Marco Pangallo; Alex Scott; Bassel Tarbush; Samuel Wiese

doi:10.1007/s00182-023-00837-4

Best-response dynamics, playing sequences, and convergence to equilibrium in random games

Int J Game Theory. 2023;52(3):703-735. doi: 10.1007/s00182-023-00837-4. Epub 2023 Jun 14.

Authors

Torsten Heinrich^{1

2

3}, Yoojin Jang^{2

4}, Luca Mungo^{2

5}, Marco Pangallo⁶, Alex Scott⁵, Bassel Tarbush⁷, Samuel Wiese^{2

4}

Affiliations

¹ Faculty for Economics and Business Administration, Chemnitz University of Technology, Chemnitz, Germany.
² Institute for New Economic Thinking at the Oxford Martin School, University of Oxford, Oxford, UK.
³ Oxford Martin Programme on Technological and Economic Change (OMPTEC), Oxford Martin School, University of Oxford, Oxford, UK.
⁴ Department of Computer Science, University of Oxford, Oxford, UK.
⁵ Mathematical Institute, University of Oxford, Oxford, UK.
⁶ CENTAI Institute, Torino, Italy.
⁷ Department of Economics, University of Oxford, Oxford, UK.

Abstract

We analyze the performance of the best-response dynamic across all normal-form games using a random games approach. The playing sequence-the order in which players update their actions-is essentially irrelevant in determining whether the dynamic converges to a Nash equilibrium in certain classes of games (e.g. in potential games) but, when evaluated across all possible games, convergence to equilibrium depends on the playing sequence in an extreme way. Our main asymptotic result shows that the best-response dynamic converges to a pure Nash equilibrium in a vanishingly small fraction of all (large) games when players take turns according to a fixed cyclic order. By contrast, when the playing sequence is random, the dynamic converges to a pure Nash equilibrium if one exists in almost all (large) games.

Keywords: Best-response dynamics; Equilibrium convergence; Random games.