%0 Journal Article %1 Taylor2007 %A Taylor, Christine %A Nowak, Martin A. %D 2007 %J Evolution %K evolution game-theory %N 10 %P 2281 %R 10.1111/j.1558-5646.2007.00196.x %T Transforming the dilemma %V 61 %X How does natural selection lead to cooperation between competing individuals? The Prisoner's Dilemma captures the essence of this problem. Two players can either cooperate or defect. The payoff for mutual cooperation, R, is greater than the payoff for mutual defection, P. But a defector versus a cooperator receives the highest payoff, T, while the cooperator obtains the lowest payoff, S. Hence, the Prisoner's Dilemma is defined by the payoff ranking T > R > P > S. In a well-mixed population, defectors always have a higher expected payoff than cooperators, and therefore natural selection favors defectors. The evolution of cooperation requires specific mechanisms. Here we discuss five mechanisms for the evolution of cooperation: direct reciprocity, indirect reciprocity, kin selection, group selection and network reciprocity (or graph selection). Each mechanism leads to a transformation of the Prisoner's Dilemma payoff matrix. From the transformed matrices, we derive the fundamental conditions for the evolution of cooperation. The transformed matrices can be used in standard frameworks of evolutionary dynamics such as the replicator equation or stochastic processes of game dynamics in finite populations.

@article{Taylor2007, abstract = {How does natural selection lead to cooperation between competing individuals? The Prisoner's Dilemma captures the essence of this problem. Two players can either cooperate or defect. The payoff for mutual cooperation, R, is greater than the payoff for mutual defection, P. But a defector versus a cooperator receives the highest payoff, T, while the cooperator obtains the lowest payoff, S. Hence, the Prisoner's Dilemma is defined by the payoff ranking T > R > P > S. In a well-mixed population, defectors always have a higher expected payoff than cooperators, and therefore natural selection favors defectors. The evolution of cooperation requires specific mechanisms. Here we discuss five mechanisms for the evolution of cooperation: direct reciprocity, indirect reciprocity, kin selection, group selection and network reciprocity (or graph selection). Each mechanism leads to a transformation of the Prisoner's Dilemma payoff matrix. From the transformed matrices, we derive the fundamental conditions for the evolution of cooperation. The transformed matrices can be used in standard frameworks of evolutionary dynamics such as the replicator equation or stochastic processes of game dynamics in finite populations.}, added-at = {2011-01-13T13:26:32.000+0100}, author = {Taylor, Christine and Nowak, Martin A.}, biburl = {https://www.bibsonomy.org/bibtex/23f4aa93b7948270dded8277e1ea718d1/rincedd}, doi = {10.1111/j.1558-5646.2007.00196.x}, file = {Taylor2007 - Transforming the Dilemma.pdf:Evolutionary Game Theory/Taylor2007 - Transforming the Dilemma.pdf:PDF}, groups = {public}, interhash = {02af07dc65faf76c1965f899f3da5737}, intrahash = {3f4aa93b7948270dded8277e1ea718d1}, journal = {Evolution}, keywords = {evolution game-theory}, number = 10, pages = 2281, timestamp = {2011-04-05T11:55:47.000+0200}, title = {Transforming the dilemma}, username = {rincedd}, volume = 61, year = 2007 }