Synchronicity in Non-smooth Competitive Networks with Threshold Nonlinearities

Ulises Chialva; Walter Reartes

Journal of Applied Nonlinear Dynamics

Miguel A. F. Sanjuan (editor), Albert C.J. Luo (editor)

Synchronicity in Non-smooth Competitive Networks with Threshold Nonlinearities

Journal of Applied Nonlinear Dynamics 8(4) (2019) 533--547 | DOI:10.5890/JAND.2019.12.002

Ulises Chialva, Walter Reartes

Departamento de Matemática, Universidad Nacional del Sur, Av. Alem 1253, 8000 Bahía Blanca, Buenos Aires, Argentina

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Abstract

The synchronization of nodes is a widely reported phenomenon in a large variety of networks. However, the mechanisms that produce such behavior can not always be studied analytically. In this paper, certain non-smooth competitive networks with linear thresholds are studied with formal and numerical tools. We show that the symmetries of the network architecture allow to display and explain the synchronicity between the nodes. Finally it is demonstrated that in this type of non-smooth networks the synchronicity constitutes a bifurcation phenomenon related to the stability of limit cycles.

Acknowledgments

The work is supported by the Universidad Nacional del Sur (Grant no. PGI 24/L096).

References

[1] Pikovsky, A., Rosenblum, M., and Kurths, J. (2003), Synchronization: a universal concept in nonlinear sciences, 12, Cambridge university press.
[2] Strogatz, S.H. (1994), Nonlinear Dynamics and Chaos With Applications To Physics, Biology, Chemistry, and Engineering, Westview Press.
[3] Kuramoto, Y. (1975), Self-entrainment of a population of coupled non-linear oscillators, International symposium on mathematical problems in theoretical physics, 420-422.

[4]	Chen, G., Zhou, J., and Liu, Z. (2004), Global synchronization of coupled delayed neural networks and applications to chaotic cnn models, International Journal of Bifurcation and Chaos, 14, 2229-2240.

[5] Fries, P., Reynolds, J.H., Rorie, A.E., and Desimone, R. (2001), Modulation of oscillatory neuronal synchronization by selective visual attention, Science, 291, 1560-1563.
[6] Varela, F., Lachaux, J.P., Rodriguez, E., and Martinerie, J. (2001), The brainweb: phase synchronization and large-scale integration, Nature reviews neuroscience, 2, 229.

[7]	Batista, A.M., Pinto, S.E.d.S., Viana, R.L., and Lopes, S.R. (2002), Lyapunov spectrum and synchronization of piecewise linear map lattices with power-law coupling, Physical Review E, 65, 056209.

[8] Arena, P., Buscarino, A., Fortuna, L., and Frasca, M. (2006), Separation and synchronization of piecewise linear chaotic systems, Physical Review E, 74, 026212.
[9] Hahnloser, R.L.T. (1998) On the piecewise analysis of networks of linear threshold neurons, Neural Networks, 11, 691-697.
[10] Hahnloser, R.H.R., Seung, H.S., and Slotine, J.J. (2003), Permitted and forbidden sets in symmetric threshold-linear networks, Neural Computation, 15, 621-638.
[11] Curto, C., Degeratu, A., and Itskov, V. (2012), Flexible memory networks, Bulletin of Mathematical Biology, 74, 590-614.
[12] Curto, C. and Morrison, K. (2016), Pattern completion in symmetric threshold-linear networks, Neural Comput., 28, 2825-2852.
[13] Ermentrout, G.B. and Terman, D.H. (2010), Mathematical Foundations of Neuroscience, 35, Springer.
[14] Morrison, K., Degeratu, A., Itskov, V., and Curto, C. (2016), Diversity of emergent dynamics in competitive threshold-linear networks: a preliminary report, ArXiv:1605.04463v1[q-bio.NC].
[15] Chialva, U. and Reartes, W. (2017), Heteroclinic cycles in a competitive network, International Journal of Bifurcation and Chaos, 27, 1730044.
[16] Parmelee, C.M. (2017), Applications of discrete mathematics for understanding dynamics of synapses and networks in neuroscience, arXiv preprint arXiv:1702.06538 .
[17] Curto, C., Degeratu, A., and Itskov, V. (2013), Encoding binary neural codes in networks of threshold-linear neurons, Neural Comput., 25, 2858-2903.