Evolutionary Dynamics in Complex Networks of Adaptive and Competing Agents
Author | : Baosheng Yuan |
Publisher | : |
Total Pages | : 10 |
Release | : 2007 |
ISBN-10 | : OCLC:1290321553 |
ISBN-13 | : |
Rating | : 4/5 (53 Downloads) |
Download or read book Evolutionary Dynamics in Complex Networks of Adaptive and Competing Agents written by Baosheng Yuan and published by . This book was released on 2007 with total page 10 pages. Available in PDF, EPUB and Kindle. Book excerpt: We use minority game model to investigate evolutionary dynamics in complex networks of adaptive agents competing for limited resources. We show that the dynamics and the associated phase structures critically depend on the underlying network organizations, and evolution is a key mechanism for the emergence of high-order coordination among the networked agents. A non-growing random directed network admits a clear phrase transition from a stable or quot;criticalquot; state to a quot;chaoticquot; state. In contrast, no such phrase transition has been detected in a growing directed network; Instead, it permits stable or quot;criticalquot; dynamics for all the connectivity. The dynamics of a scale-free directed network is found sensitive to its connectivity if a small fraction of link reversal is allowed in the network: The evolutionary dynamics exhibits a gradual phase transition from the stable (or quot;criticalquot;) state to the quot;chaoticquot; regime with increase of the connectivity number K; this suggests that the scale-free directed network is vulnerable to a small fraction of quot;errorsquot; in its network organization. The underlying sources for the emergence of these dynamics are the organizations of the networks and can be understood with a descendant clusters theory. Evolution dramatically enhances the performance of a system in a stable or quot;criticalquot; regime, but has no effect on a system in quot;chaoticquot; state; such attribute can be empowered to typify the dynamics of a complex network. The impact of evolution on system efficiency lies in its ability in reducing quot;crowdednessquot; of agents' strategies and can be explained by a crowd-anticrowd theory.