Heteroclinic chaotic behavior driven by a Brownian motion

Shen, Jun; Lu, Kening; Zhang, Weinian

doi:10.1016/j.jde.2013.08.003

Cited by 40 publications

(23 citation statements)

References 23 publications

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“…It is worth mentioning that there are numerous works in the literature on the existence of attractors for standard stochastic equations driven by a white noise, see, [1,2,3,4,5,6,7,8,9,11,13,20,22,23,24,33,34,35,36,38,41]. The dynamical behavior of standard stochastic equations driven by colored noise or Wong-Zakai approximation process have been examined in [15,16,29,30,31,32,40]. Recently, the random dynamics is investigated for fractional nonclassical diffusion equations driven by colored noise [39].…”

Section: Dingshi LI Xiaohu Wang and Junyilang Zhaomentioning

confidence: 99%

Limiting dynamical behavior of random fractional FitzHugh-Nagumo systems driven by a Wong-Zakai approximation process

Li¹,

Wang²,

Zhao³

2020

Communications on Pure &Amp; Applied Analysis

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In this paper, we study the long term behavior of non-autonomous fractional FitzHugh-Nagumo systems with random forcing given by an approximation of white noise, called Wong-Zakai approximation. We first prove the existence and uniqueness of tempered pullback attractors for the Wong-Zakai approximation fractional FitzHugh-Nagumo systems, and then establish the upper semicontinuity of attractors of system driven by a linear multiplicative Wong-Zakai approximations as random forcing approaches white noise in some sense.

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Section: Dingshi LI Xiaohu Wang and Junyilang Zhaomentioning

confidence: 99%

Limiting dynamical behavior of random fractional FitzHugh-Nagumo systems driven by a Wong-Zakai approximation process

Li¹,

Wang²,

Zhao³

2020

Communications on Pure &Amp; Applied Analysis

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“…In the pioneer work about approximations, Wong and Zakai [40,41] studied the approximations for one-dimensional Brownian motion. Their work was later extended to stochastic differential equations of higher dimension ( [18,19,22,27,35,33,34,36]). The Wong-Zakai approximations have also been generalized to stochastic differential equations driven by martingales and semi-martingales ( [24,25,29,30]).…”

Section: Min Yang and Guanggan Chenmentioning

confidence: 99%

Finite dimensional reducing and smooth approximating for a class of stochastic partial differential equations

Yang¹,

Guang-gan²

2020

Discrete &Amp; Continuous Dynamical Systems - B

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This work provides a finite dimensional reducing and a smooth approximating for a class of stochastic partial differential equations with an additive white noise. Using the invariant random cone to show the asymptotical completion, this stochastic partial differential equation is reduced to a stochastic ordinary differential equation on a random invariant manifold. Furthermore, after deriving the finite dimensional reducing for another stochastic partial differential equation driven by a Wong-Zakai scheme via a smooth colored noise, it is proved that when the smooth colored noise tends to the white noise, the solution and the finite dimensional reducing of the approximate system converge pathwisely to those of the original system.

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“…Using deterministic differential equations to approximate stochastic differential equations was introduced by Wong and Zakai in their pioneer work [60,59] in which they discussed both piecewise linear approximations and piecewise smooth approximations for one-dimensional Brownian motions. Their work was later generalized to stochastic differential equations of higher dimensions, for example, by McShane [37], Stroock and Varadhan [45], Sussmann [46,47], Ikeda et al [22], Ikeda and Watanabe [23], and recently by Kelly and Melbourne [24], and Shen and Lu [43] in which the same approximations as this paper were studied. The results of the Wong-Zakai approximations have also been extended to stochastic differential equations driven by martingales and semimartingales, see for example, Nakao and Yamato [39], Konecny [25], Protter [41], Nakao [38], and Kurtz and Protter [26,27].…”

mentioning

confidence: 97%

“…(3) generates a random dynamical system, which allows us to investigate the pathwise dynamics such as random attractors. Such approximation was also used in Lu and Wang [36,35], Wang et al [58], and Shen et al [43] where they studied the chaotic behavior of random differential equations driven by a multiplicative noise of G δ (θ t ω) and long term behavior of stochastic reaction-diffsion equations driven by multiplicative noise .…”

mentioning

confidence: 99%

Wong-Zakai approximations and asymptotic behavior of stochastic Ginzburg-Landau equations

Ma¹,

Shu²,

Qin³

2017

Discrete &Amp; Continuous Dynamical Systems - B

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In this paper we discuss the Wong-Zakai approximations given by a stationary process via the Wiener shift and their associated long term pathwise behavior for stochastic Ginzburg-Landau equations driven by a white noise. We first apply the Galerkin method and compactness argument to prove the existence and uniqueness of weak solutions. Consequently, we show that the approximate equation has a pullback random attractor under much weaker conditions than the original stochastic equation. At last, when the stochastic Ginzburg-Landau equation is driven by a linear multiplicative noise, we establish the convergence of solutions of Wong-Zakai approximations and the upper semicontinuity of random attractors of the approximate random system as the size of approximation approaches zero.2010 Mathematics Subject Classification. Primary: 37L55, 60H15; Secondary: 35Q56.

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Heteroclinic chaotic behavior driven by a Brownian motion

Cited by 40 publications

References 23 publications

Limiting dynamical behavior of random fractional FitzHugh-Nagumo systems driven by a Wong-Zakai approximation process

Limiting dynamical behavior of random fractional FitzHugh-Nagumo systems driven by a Wong-Zakai approximation process

Finite dimensional reducing and smooth approximating for a class of stochastic partial differential equations

Wong-Zakai approximations and asymptotic behavior of stochastic Ginzburg-Landau equations

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