Hyperbolic Chaos of Turing Patterns

Kuptsov, Pavel V.; Кузнецов, С. П.; Pikovsky, Arkady

doi:10.1103/physrevlett.108.194101

Cited by 12 publications

(19 citation statements)

References 17 publications

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“…With this interpretation, our results demonstrate that an interaction between blinking patterns results in a chaotic relocation of their positions, moreover, this chaos is hyperbolic. A kind of such behavior was reported recently in a model of interacting Turing patterns with different wave numbers [24]. The presented model based on the nonlinear Fokker-Plank equation provides another indication that the above mechanism of the hyperbolic chaos is realizable in quite generic circumstances.…”

Section: Discussionsupporting

confidence: 64%

Hyperbolic chaos at blinking coupling of noisy oscillators

2013

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We study an ensemble of identical noisy phase oscillators with a blinking mean-field coupling, where one-cluster and two-cluster synchronous states alternate. In the thermodynamic limit the population is described by a nonlinear Fokker-Planck equation. We show that the dynamics of the order parameters demonstrates hyperbolic chaos. The chaoticity manifests itself in phases of the complex mean field, which obey a strongly chaotic Bernoulli map. Hyperbolicity is confirmed by numerical tests based on the calculations of relevant invariant Lyapunov vectors and Lyapunov exponents. We show how the chaotic dynamics of the phases is slightly smeared by finite-size fluctuations.

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Section: Discussionsupporting

confidence: 64%

Hyperbolic chaos at blinking coupling of noisy oscillators

2013

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“…Replacing the spatial differentiation operator in equation of Ref. [4] with a difference operator, we obtain , ) 1 where u j is dynamical variable related to the j-th spatial cell, k, A, ε are parameters. The quantities d j define the spatial non-homogeniety, the role of which will be explained below.…”

Section: Nonautonomous Lattice System Generating Turing Patternsmentioning

confidence: 99%

“…2 S. P. Kuznetsov ______________________________ CHEBOKSARY, 2-6 JUNE, 2019 ______________________________ the three-dimensional state space, but such attractors can occur in spaces of higher dimension too.Physical examples of systems with attractors of Smale -Williams type can be constructed using oscillators residing in states of excitation and inhibition alternately, while the angular variable has a sense of the oscillator phase [3]. Another approach is based on treatment of patterns arising in an active medium, say, that for Turing structures or standing waves, and the angular variable is a spatial phase [4,5,6]. A disadvantage of the first approach is that it requires, as a rule, a use of rather complex external driving for parameter modulation, combining low-frequency and high-frequency components.…”

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Some Lattice Models with Hyperbolic Chaotic Attractors

Кузнецов¹

2020

Nelin. Dinam.

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Examples of one-dimensional lattice systems are considered, in which patterns of different spatial scales arise alternately, so that the spatial phase over a full cycle undergo transformation according to expanding circle map that implies occurrence of Smale -Williams attractors in the multidimensional state space. These models can serve as a basis for design electronic generators of robust chaos within a paradigm of coupled cellular networks. One of the examples is a mechanical pendulum system interesting and demonstrative for research and educational experimental studies. 2 S. P. Kuznetsov ______________________________ CHEBOKSARY, 2-6 JUNE, 2019 ______________________________ the three-dimensional state space, but such attractors can occur in spaces of higher dimension too.Physical examples of systems with attractors of Smale -Williams type can be constructed using oscillators residing in states of excitation and inhibition alternately, while the angular variable has a sense of the oscillator phase [3]. Another approach is based on treatment of patterns arising in an active medium, say, that for Turing structures or standing waves, and the angular variable is a spatial phase [4,5,6]. A disadvantage of the first approach is that it requires, as a rule, a use of rather complex external driving for parameter modulation, combining low-frequency and high-frequency components. Within the second approach, instead of high-frequency modulation a spatial non-homogeneity is introduced that is effortless. A disadvantage is a need of exploiting systems of infinite dimension of the state space, which complicates mathematical description and practical implementations.An interesting seems application of the second approach for organizing hyperbolic chaos in finite-dimensional systems, namely, in lattices of cells, whose dynamics are governed by ordinary differential equations. In this concern, it is worth mentioning a paradigm of cellular neural networks (CNN) on a base of electronic components designed as arrays of cells arranged in space [7]. These systems were suggested, particularly, for parallel data processing, as an alternative to traditional computational approaches. As one of the directions, application of CNN was considered for analog modeling of complex space-time dynamics including Turing structures, spiral patterns, turbulence.This article discusses three models of one-dimensional cell arrays, which can inspire design of CNN generating rough chaos.

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“…Требуемое преобразование фазы в уже известных примерах физически осуществля-ется разными способами. Системы с аттракторами типа Смейла -Вильямса могут иметь различную физическую природу (механическую, химическую, радиофизическую) и пред-ставлять собой связанные осцилляторы, между которыми возмущение передается резонанс-ным и нерезонансным образом [13], кольцевые цепочки осцилляторов, вдоль которых пере-дается возмущение [14], системы параметрических осцилляторов, в которых роль угловой переменной может выполнять соотношение амплитуд осцилляторов [15], распределенные системы, в которых особым образом взаимодействуют пространственные гармоники волно-вых паттернов [16], системы на основе взаимодействующих ансамблей фазовых осцилля-торов с глобальной связью, в которых угловой переменной является аргумент параметра порядка [17].…”

Section: Introductionunclassified