Synchronization of networks with prescribed degree distributions

Abstract

We show that the degree distributions of graphs do not suffice to characterize the synchronization of systems evolving on them. We prove that, for any given degree sequence satisfying certain conditions, there exists a connected graph having that degree sequence for which the first nontrivial eigenvalue of the graph Laplacian is arbitrarily close to zero. Consequently, complex dynamical systems defined on such graphs have poor synchronization properties. The result holds under quite mild assumptions, and shows that there exists classes of random, scale-free, regular, small-world, and other common network architectures which impede synchronization. The proof is based on a construction that also serves as an algorithm for building nonsynchronizing networks having a prescribed degree distribution.

Keywords

All Related Versions

This publication has 22 references indexed in Scilit:

Delays, Connection Topology, and Synchronization of Coupled Chaotic Maps
Physical Review Letters, 2004
Synchronization and desynchronization of complex dynamical networks: an engineering viewpoint
IEEE Transactions on Circuits and Systems I: Regular Papers, 2003
Heterogeneity in Oscillator Networks: Are Smaller Worlds Easier to Synchronize?
Physical Review Letters, 2003
Evolving networks with distance preferences
Physical Review E, 2002
Synchronization in Small-World Systems
Physical Review Letters, 2002
Spectral properties and synchronization in coupled map lattices
Physical Review E, 2001
An introduction to the synchronization of chaotic systems: coupled skew tent maps
IEEE Transactions on Circuits and Systems I: Regular Papers, 1997
Asymptotic enumeration by degree sequence of graphs with degreeso(n 1/2)
Combinatorica, 1991
Symmetry breaking bifurcation for coupled chaotic attractors
Journal of Physics A: General Physics, 1991
On the concept of attractor
Communications in Mathematical Physics, 1985