Title :
Algorithmic Renormalization for Network Dynamics
Author :
Chazelle, Bernard
Author_Institution :
Dept. of Comput. Sci., Princeton Univ., Princeton, NJ, USA
fDate :
Jan.-March 1 2015
Abstract :
The aim of this work is to give a full, elementary exposition of a recently introduced algorithmic technique for renormalizing dynamic networks. The motivation is the analysis of time-varying graphs. We begin by showing how an arbitrary sequence of graphs over a fixed set of nodes can be parsed so as to capture hierarchically how information propagates across the nodes. Equipped with parse trees, we are then able to analyze the dynamics of averaging-based multiagent systems. We investigate the case of diffusive influence systems and build a renormalization framework to help resolve their long-term behavior. Introduced as a generalization of the Hegselmann-Krause model of multiagent consensus, these systems allow the agents to have their own, distinct communication rules. We formulate new criteria for the asymptotic periodicity of such systems.
Keywords :
generalisation (artificial intelligence); multi-agent systems; network theory (graphs); renormalisation; trees (mathematics); Hegselmann-Krause model generalization; algorithmic renormalization; arbitrary graph sequence; asymptotic periodicity; averaging-based multiagent system; diffusive influence systems; distinct communication rule; multiagent consensus; network dynamics; parse trees; time-varying graph; Chaos; Encoding; Heuristic algorithms; Limit-cycles; Orbits; Polynomials; Robustness; Dynamic networks; influence systems; renormalization;
Journal_Title :
Network Science and Engineering, IEEE Transactions on
DOI :
10.1109/TNSE.2015.2419133
