Similarity Networks of the Functional Evolution of Cycles in Structural Networks

David M. Walker; Antoinette Tordesillas; Gary Froyland

Summary

Proceedings of the 2012 International Symposium on Nonlinear Theory and its Applications

2012

Session Number:B4L-C

Session:

Number:502

Similarity Networks of the Functional Evolution of Cycles in Structural Networks

David M. Walker, Antoinette Tordesillas, Gary Froyland,

pp.502-505

Publication Date:

Online ISSN:2188-5079

DOI:10.15248/proc.1.502

PDF download (480.1KB)

Summary:

We construct networks summarizing similarity of local mesoscopic cycle evolution within structural contact networks of quasistatically deforming dense granular materials. In essence, at each stage of the deformation, a contact network is created and a minimal cycle basis is calculated. For each grain we compare its local mesoscopic cycle topology across a specified strain (or temporal) interval and summarize this evolution in a similarity network. We propose a prescription for finding a suitably sized strain interval. Concentrating on times when stick-slip or jamming-unjamming behaviour is evident we relate properties of the similarity networks (e.g., community structures) to areas of failure throughout the material.

References:

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