Visible to the public A fresh look at network science: Interdependent multigraphs models inspired from statistical physics

TitleA fresh look at network science: Interdependent multigraphs models inspired from statistical physics
Publication TypeConference Paper
Year of Publication2014
AuthorsBaras, J.S.
Conference NameCommunications, Control and Signal Processing (ISCCSP), 2014 6th International Symposium on
Date PublishedMay
Keywordsbiological network, Biological system modeling, coevolving multigraphs, Collaboration, collaboration multigraphs, collaborative control, communication multigraphs, communication network, communication topology, complex networks, constrained coalitional games, constrained coalitional network games, control network, cooperative multi-agent systems, cooperative swarms, distributed task execution, economic network, expander graphs, game theory, Games, Human Behavior, hybrid network, interacting dynamic multigraphs, interdependent multigraphs models, multi-robot systems, multimetric problems, network science, network science perspective, network theory (graphs), Network topology, Peer-to-peer computing, Physics, social network, SoS Lablet, statistical physics, Stochastic processes, Trust, Trust, Recommendation Systems, and Collaboration
Abstract

We consider several challenging problems in complex networks (communication, control, social, economic, biological, hybrid) as problems in cooperative multi-agent systems. We describe a general model for cooperative multi-agent systems that involves several interacting dynamic multigraphs and identify three fundamental research challenges underlying these systems from a network science perspective. We show that the framework of constrained coalitional network games captures in a fundamental way the basic tradeoff of benefits vs. cost of collaboration, in multi-agent systems, and demonstrate that it can explain network formation and the emergence or not of collaboration. Multi-metric problems in such networks are analyzed via a novel multiple partially ordered semirings approach. We investigate the interrelationship between the collaboration and communication multigraphs in cooperative swarms and the role of the communication topology, among the collaborating agents, in improving the performance of distributed task execution. Expander graphs emerge as efficient communication topologies for collaborative control. We relate these models and approaches to statistical physics.

URLhttp://ieeexplore.ieee.org/document/6877921/
DOI10.1109/ISCCSP.2014.6877921
Citation Key6877921