Optional games on cycles and complete graphs

Hyeong Chai Jeong; Seung Yoon Oh; Benjamin Allen; Martin A. Nowak

doi:10.1016/j.jtbi.2014.04.025

Optional games on cycles and complete graphs

Hyeong Chai Jeong, Seung Yoon Oh, Benjamin Allen, Martin A. Nowak

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

31 Scopus citations

Abstract

We study stochastic evolution of optional games on simple graphs. There are two strategies, A and B, whose interaction is described by a general payoff matrix. In addition, there are one or several possibilities to opt out from the game by adopting loner strategies. Optional games lead to relaxed social dilemmas. Here we explore the interaction between spatial structure and optional games. We find that increasing the number of loner strategies (or equivalently increasing mutational bias toward loner strategies) facilitates evolution of cooperation both in well-mixed and in structured populations. We derive various limits for weak selection and large population size. For some cases we derive analytic results for strong selection. We also analyze strategy selection numerically for finite selection intensity and discuss combined effects of optionality and spatial structure.

Original language	English
Pages (from-to)	98-112
Number of pages	15
Journal	Journal of Theoretical Biology
Volume	356
DOIs	https://doi.org/10.1016/j.jtbi.2014.04.025
State	Published - Sep 7 2014
Externally published	Yes

Funding

Support from the program for Foundational Questions in Evolutionary Biology (FQEB) , the National Philanthropic Trust, the John Templeton Foundation and the National Research Foundation of Korea grant ( NRF-2010-0022474 ) is gratefully acknowledged.

Keywords

Evolution of cooperation
Evolutionary game theory
Evolutionary graph theory
Spatial games

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10.1016/j.jtbi.2014.04.025

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title = "Optional games on cycles and complete graphs",

abstract = "We study stochastic evolution of optional games on simple graphs. There are two strategies, A and B, whose interaction is described by a general payoff matrix. In addition, there are one or several possibilities to opt out from the game by adopting loner strategies. Optional games lead to relaxed social dilemmas. Here we explore the interaction between spatial structure and optional games. We find that increasing the number of loner strategies (or equivalently increasing mutational bias toward loner strategies) facilitates evolution of cooperation both in well-mixed and in structured populations. We derive various limits for weak selection and large population size. For some cases we derive analytic results for strong selection. We also analyze strategy selection numerically for finite selection intensity and discuss combined effects of optionality and spatial structure.",

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AU - Jeong, Hyeong Chai

AU - Oh, Seung Yoon

AU - Allen, Benjamin

AU - Nowak, Martin A.

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N2 - We study stochastic evolution of optional games on simple graphs. There are two strategies, A and B, whose interaction is described by a general payoff matrix. In addition, there are one or several possibilities to opt out from the game by adopting loner strategies. Optional games lead to relaxed social dilemmas. Here we explore the interaction between spatial structure and optional games. We find that increasing the number of loner strategies (or equivalently increasing mutational bias toward loner strategies) facilitates evolution of cooperation both in well-mixed and in structured populations. We derive various limits for weak selection and large population size. For some cases we derive analytic results for strong selection. We also analyze strategy selection numerically for finite selection intensity and discuss combined effects of optionality and spatial structure.

AB - We study stochastic evolution of optional games on simple graphs. There are two strategies, A and B, whose interaction is described by a general payoff matrix. In addition, there are one or several possibilities to opt out from the game by adopting loner strategies. Optional games lead to relaxed social dilemmas. Here we explore the interaction between spatial structure and optional games. We find that increasing the number of loner strategies (or equivalently increasing mutational bias toward loner strategies) facilitates evolution of cooperation both in well-mixed and in structured populations. We derive various limits for weak selection and large population size. For some cases we derive analytic results for strong selection. We also analyze strategy selection numerically for finite selection intensity and discuss combined effects of optionality and spatial structure.

KW - Evolution of cooperation

KW - Evolutionary game theory

KW - Evolutionary graph theory

KW - Spatial games

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Optional games on cycles and complete graphs

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