Dynamics of coupled mode solitons in bursting neural networks

Nfor, Nkeh Oma; Ghomsi, P. Guemkam; Kakmeni, F. M. Moukam

doi:10.1103/physreve.97.022214

Cited by 23 publications

(20 citation statements)

References 74 publications

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“…We now focus on high degree of oceanic inter plate coupling at subduction zones in which 𝛾 ≠ 0 [Nkomom et al, 2021;Akishin et al, 2000;Pelap et al, 2016]. Consequently we consider small amplitude oscillation wave solution to equation ( 10), by employing the multiple-scale method [Remoissenet, 1986;Nfor et al, 2021;Nfor, 2021;Nfor et al, 2018;Nfor and Mokoli, 2016]. We initially introduce the change of variable…”

Section: Nonlinear Wave Dynamics In Subduction Zonesmentioning

confidence: 99%

On the possibility of rogue wave generation based on the dynamics of modified Burridge-Knopoff model of earthquake fault

Nfor

Ndoh²,

Tingue³

et al. 2023

Annals of Geophysics

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In this study we propose a modified Burridge‐Knopoff model of earthquake fault, in which two tectonic plates are strongly coupled by nonlinear springs. By minimizing the effects of the veloci‐ ty‐weakening stick‐slip friction force between the masses and the moving surface, and in the limit of low amplitude oscillations; the system exhibits both stick‐slip and damped oscillatory motions as the values of some parameters are varied. Such motions usually characterize the dynamics of an earthquake fault, even though it is not always felt because of the low amplitude of vibrations. However when enough stress builds up in the subduction zones to overcome the frictional forces between tectonic plates, the oceanic rocks suddenly slip and there is violent release of energy at the epicentre. This outburst of energy simply signifies the generation of a very large amplitude and localized nonlinear wave. Such wave profile exactly fits the Peregrine solution of the damped/ forced nonlinear Schrodinger amplitude equation, derived from the modified one‐dimensional Burridge‐Knopoff equation of motion. In the regime of minimal or no frictional forces, these mon‐ ster waves suddenly appear and disappear without traces as shown by the numerical investigations. Our results strongly suggest that rogue waves emanates from the dynamics of nonlinearly coupled tectonic plates in subduction zones. This is further complemented by the fact that these giant waves were initially observed in Pacific and Atlantic oceans, which play hosts to the world’s largest oceanic subduction zones.

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Section: Nonlinear Wave Dynamics In Subduction Zonesmentioning

confidence: 99%

On the possibility of rogue wave generation based on the dynamics of modified Burridge-Knopoff model of earthquake fault

Nfor

Ndoh²,

Tingue³

et al. 2023

Annals of Geophysics

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“…Enormous effort has been made to obtain analytical solutions to a number of discrete nonlinear partial differential equations. Some prominent analytical methods includes: quadrature method, ansatz method, method of separation of variables, Painlevé method, Hirota method, IST method, B äcklund transform method, Darboux transformation method among others [11,18,51,[53][54][55][56]. Furthermore, a more powerful analytical method like the discrete generalized (m, N − m)-fold Darboux transformation technique; have already been developed to obtain two-component localized wave solutions for a reduced semi-discrete two-component coupled system on a two-chain lattice [57].…”

Section: Discrete Localized Modesmentioning

confidence: 99%

“…Since the discovery of solitary waves by John Scott Russell, solitons have been experimentally observed in many spatially discrete physical systems, such as granular materials, nonlinear Hamiltonian lattices [10], electrical transmission lines, and neural networks [11][12][13][14]. The recurrence phenomenon was originally observed in the Fermi-Pasta-Ulam lattice [15,16].…”

Section: Introductionmentioning

confidence: 99%

Modulational Instability and Discrete Localized Modes in Two Coupled Atomic Chains with Next-Nearest-Neighbor Interactions

Nfor

Yamgoué

2022

J Nonlinear Math Phys

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A pair of one dimensional atomic chains which are coupled via the Klein-Gordon potential is considered in this study, with each chain experiencing both nearest and next-nearest-neighbor interactions. The discrete nonlinear Schrödinger amplitude equation with next-nearest-neighbor interactions is thus derived from the out-phase equation of motion of the coupled chains. This is achieved by using the rotating wave approximations perturbation method, in which both the carrier wave and envelope are explicitly treated in the discrete regime. It is shown that the next-nearest-neighbor interactions greatly modifies the region of observation of modulational instability in the atomic chain. By exploring the discrete Hirota-Bilinear method, we obtain the discrete one-soliton solution which is localized around the origin and structurally stable because it conserves it form as time evolves. However when the atomic chain is purely subjected to a symmetric coupling potential, we observe a structurally unstable discrete excitation that changes into an up-and-down asymmetric localized modes; both in the presence and absence of next-nearest-neighbor interactions. Results of numerical simulations clearly depicts the long term evolution of these discrete nonlinear excitations, that evolve from symmetric to asymmetric localized modes in the atomic chain.

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“…The dynamics of different classes of neural networks have been widely studied in recent years. [1][2][3][4][5][6][7][8][9][10][11][12][13] For the Cohen-Grossberg neural networks:…”

Section: Introductionmentioning

confidence: 99%

“…A good neural network is expected to be robust against such uncertainties. The dynamics of different classes of neural networks have been widely studied in recent years 1–13 …”

Section: Introductionmentioning

confidence: 99%

Dynamics of interval Cohen‐Grossberg neural networks with time‐varying delays based on LMI computation

Tan

Song

Liu

et al. 2018

Concurrency and Computation

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The problem of the global robust exponential stability of delayed interval Cohen-Grossberg neural networks is considered. By constructing suitable Lyapunov functional and using the linear matrix inequality (LMI) technique, some sufficient conditions are derived to ensure the existence, uniqueness and robust exponential stability of the equilibrium point. Based on LMI computation, numerical examples are employed to show that the new results are less restrictive and less conservative than some existing results in the literature. KEYWORDS Cohen-Grossberg model, dynamics of neural networks, global robust exponential stability, interval delayed neural networks, linear matrix inequality (LMI)

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Dynamics of coupled mode solitons in bursting neural networks

Cited by 23 publications

References 74 publications

On the possibility of rogue wave generation based on the dynamics of modified Burridge-Knopoff model of earthquake fault

On the possibility of rogue wave generation based on the dynamics of modified Burridge-Knopoff model of earthquake fault

Modulational Instability and Discrete Localized Modes in Two Coupled Atomic Chains with Next-Nearest-Neighbor Interactions

Dynamics of interval Cohen‐Grossberg neural networks with time‐varying delays based on LMI computation

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