Attractor symmetry and stability in symmetric self-driven oscillator networks

Ian Hunter; Michael Norton; James Sheehy; Bolun Chen; Youssef Fahmy; Lanijah Flagg; Chris Simonetti; Seth Fraden

Attractor symmetry and stability in symmetric self-driven oscillator networks

ORAL

Abstract

The dynamics governing networks of identical oscillators are unchanged by node interchange symmetries, or automorphisms, of the network. Equivariant dynamical system theory predicts such networks consequently must possess steady states, and flow invariant manifolds where particular nodes, exchanged by subgroups of network symmetries, are synchronized. Homogeneous microreactors containing the oscillatory Belousov Zhabotinsky (BZ) reaction, coupled by diffusion, allow the experimental study of symmetric self-driven oscillator networks. A ring of 4 inhibitory-coupled BZ reactors was studied as a model system. This system exhibits symmetric gaits found in quadrupedal animals as its attractors. Experimental invariant manifolds, steady states, and stabilities are compared to those theoretically predicted using methods generalizable to other networks.

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We acknowledge financial support from the NSF DMREF-1534890 and the microfluidics facility of the NSF MRSEC DMR-1420382.

March 4, 2019, 11:27 AM – March 4, 2019, 11:39 AM

Presenters

Ian Hunter
- Physics, Brandeis University

Authors

Ian Hunter
- Physics, Brandeis University
Michael Norton
- Brandeis University
- Physics, Brandeis University
James Sheehy
- Physics, Brandeis University
Bolun Chen
- Brandeis University
- Neuroscience, Brandeis University
Youssef Fahmy
- Physics, Brandeis University
Lanijah Flagg
- Physics, Hampton University
Chris Simonetti
- Brandeis University
- Physics, Brandeis University
Seth Fraden
- Physics, Brandeis University
- Brandeis University
- Physics Department, Brandeis University
- Department of Physics, Brandeis University