Evolution of cooperation on stochastic dynamical networks.

Cooperative behavior that increases the fitness of others at a cost to oneself can be promoted by natural selection only in the presence of an additional mechanism. One such mechanism is based on population structure, which can lead to clustering of cooperating agents. Recently, the focus has turned...

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Main Authors: Bin Wu, Da Zhou, Feng Fu, Qingjun Luo, Long Wang, Arne Traulsen
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2010-01-01
Series:PLoS ONE
Online Access:http://europepmc.org/articles/PMC2894855?pdf=render
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spelling doaj-3ee5ae5269c549d197d5c8625b9956382020-11-24T21:48:32ZengPublic Library of Science (PLoS)PLoS ONE1932-62032010-01-0156e1118710.1371/journal.pone.0011187Evolution of cooperation on stochastic dynamical networks.Bin WuDa ZhouFeng FuQingjun LuoLong WangArne TraulsenCooperative behavior that increases the fitness of others at a cost to oneself can be promoted by natural selection only in the presence of an additional mechanism. One such mechanism is based on population structure, which can lead to clustering of cooperating agents. Recently, the focus has turned to complex dynamical population structures such as social networks, where the nodes represent individuals and links represent social relationships. We investigate how the dynamics of a social network can change the level of cooperation in the network. Individuals either update their strategies by imitating their partners or adjust their social ties. For the dynamics of the network structure, a random link is selected and breaks with a probability determined by the adjacent individuals. Once it is broken, a new one is established. This linking dynamics can be conveniently characterized by a Markov chain in the configuration space of an ever-changing network of interacting agents. Our model can be analytically solved provided the dynamics of links proceeds much faster than the dynamics of strategies. This leads to a simple rule for the evolution of cooperation: The more fragile links between cooperating players and non-cooperating players are (or the more robust links between cooperators are), the more likely cooperation prevails. Our approach may pave the way for analytically investigating coevolution of strategy and structure.http://europepmc.org/articles/PMC2894855?pdf=render
collection DOAJ
language English
format Article
sources DOAJ
author Bin Wu
Da Zhou
Feng Fu
Qingjun Luo
Long Wang
Arne Traulsen
spellingShingle Bin Wu
Da Zhou
Feng Fu
Qingjun Luo
Long Wang
Arne Traulsen
Evolution of cooperation on stochastic dynamical networks.
PLoS ONE
author_facet Bin Wu
Da Zhou
Feng Fu
Qingjun Luo
Long Wang
Arne Traulsen
author_sort Bin Wu
title Evolution of cooperation on stochastic dynamical networks.
title_short Evolution of cooperation on stochastic dynamical networks.
title_full Evolution of cooperation on stochastic dynamical networks.
title_fullStr Evolution of cooperation on stochastic dynamical networks.
title_full_unstemmed Evolution of cooperation on stochastic dynamical networks.
title_sort evolution of cooperation on stochastic dynamical networks.
publisher Public Library of Science (PLoS)
series PLoS ONE
issn 1932-6203
publishDate 2010-01-01
description Cooperative behavior that increases the fitness of others at a cost to oneself can be promoted by natural selection only in the presence of an additional mechanism. One such mechanism is based on population structure, which can lead to clustering of cooperating agents. Recently, the focus has turned to complex dynamical population structures such as social networks, where the nodes represent individuals and links represent social relationships. We investigate how the dynamics of a social network can change the level of cooperation in the network. Individuals either update their strategies by imitating their partners or adjust their social ties. For the dynamics of the network structure, a random link is selected and breaks with a probability determined by the adjacent individuals. Once it is broken, a new one is established. This linking dynamics can be conveniently characterized by a Markov chain in the configuration space of an ever-changing network of interacting agents. Our model can be analytically solved provided the dynamics of links proceeds much faster than the dynamics of strategies. This leads to a simple rule for the evolution of cooperation: The more fragile links between cooperating players and non-cooperating players are (or the more robust links between cooperators are), the more likely cooperation prevails. Our approach may pave the way for analytically investigating coevolution of strategy and structure.
url http://europepmc.org/articles/PMC2894855?pdf=render
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