Strong convergence rates for nonlinearity-truncated Euler-type approximations of stochastic Ginzburg–Landau equations

Becker, S.; Jentzen, Arnulf

doi:10.1016/j.spa.2018.02.008

Cited by 55 publications

(85 citation statements)

References 57 publications

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“…For SPDEs with non-Lipschitz coefficients, there only exist a few results about the strong convergence rates of numerical schemes (see e.g. [2,3,8,9,12]). The strong convergence rates of numerical schemes, especially the temporal discretization, is far from being understood and it is still an open problem to derive general strong convergence rates of numerical schemes for SPDEs with non-globally Lipschitz coefficients.…”

Section: Introductionmentioning

confidence: 99%

Strong convergence rates of semidiscrete splitting approximations for the stochastic Allen–Cahn equation

Bréhier

Cui

Hong

2018

IMA Journal of Numerical Analysis

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This article analyzes an explicit temporal splitting numerical scheme for the stochastic Allen-Cahn equation driven by additive noise, in a bounded spatial domain with smooth boundary in dimension d ≤ 3. The splitting strategy is combined with an exponential Euler scheme of an auxiliary problem.When d = 1 and the driving noise is a space-time white noise, we first show some a priori estimates of this splitting scheme. Using the monotonicity of the drift nonlinearity, we then prove that under very mild assumptions on the initial data, this scheme achieves the optimal strong convergence rate O(δt 1 4 ). When d ≤ 3 and the driving noise possesses some regularity in space, we study exponential integrability properties of the exact and numerical solutions. Finally, in dimension d = 1, these properties are used to prove that the splitting scheme has a strong convergence rate O(δt).2010 Mathematics Subject Classification. Primary 60H35; Secondary 60H15, 65M15.

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Section: Introductionmentioning

confidence: 99%

Strong convergence rates of semidiscrete splitting approximations for the stochastic Allen–Cahn equation

Bréhier

Cui

Hong

2018

IMA Journal of Numerical Analysis

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“…Over the past decades, there have been plenty of research articles analyzing numerical discretizations of parabolic stochastic partial differential equations (SPDEs), see, e.g., monographs [21,25] and references therein. In contrast to an overwhelming majority of literature focusing on numerical analysis of SPDEs with globally Lipschitz nonlinearity, only a limited number of papers investigated numerical SPDEs in the non-globally Lipschitz regime [1][2][3][4][5]10,11,13,15,16,19,24] and it is still far from well-understood. As a typical example of parabolic SPDEs with non-globally Lipschitz nonlinearity, stochastic Allen-Cahn equations, perturbed by additive or multiplicative noises, have received increasing attention in the last few years.…”

Section: Introductionmentioning

confidence: 99%

“…The nonlinear mapping F is assumed to be a Nemytskij operator, given by F (u)(x) = f (u(x)), x ∈ D, with f (v) = v − v 3 , v ∈ R. Such problem is often referred to as stochastic Allen-Cahn equation. Under further assumptions specified later, particularly including A γ−1 2 Q 1 2 L 2 < ∞, for some γ ∈ [1,2], (1.2) it is proved in Theorems 2.5, 2.6 that the problem (1.1) possesses a unique mild solution,…”

Section: Introductionmentioning

confidence: 99%

“…Particularly, the authors of [3] used exponential integrability properties of exact and numerical solutions to identify a strong convergence rate of order 1, but only valid in one space dimension, when the additive noise is moderately smooth, i.e., γ = 2 in (1.2). For the space-time white noise case, various discretizations were investigated in other contributions [1,2,24,30].…”

Section: Introductionmentioning

confidence: 99%

“…In the sequel we treat the above four terms one by one. Thanks to (2.4), (2.18), (2.14) and (2.13), we derive, for γ ∈ [1,2] and any fixed δ 0 ∈ ( 3 2 , 2),…”

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confidence: 99%

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Optimal Error Estimates of Galerkin Finite Element Methods for Stochastic Allen–Cahn Equation with Additive Noise

Wang

2019

J Sci Comput

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Strong approximation errors of both finite element semi-discretization and spatiotemporal full discretization are analyzed for the stochastic Allen-Cahn equation driven by additive trace-class noise in space dimension d ≤ 3. The full discretization is realized by combining the standard finite element method with the backward Euler timestepping scheme. Distinct from the globally Lipschitz setting, the error analysis becomes rather challenging and demanding, due to the presence of the cubic nonlinearity in the underlying model. By introducing two auxiliary approximation processes, we do appropriate decomposition of the considered error terms and propose a novel approach of error analysis, to successfully recover the expected convergence rates of the numerical schemes. The approach is ingenious and does not rely on high-order spatial regularity properties of the approximation processes. It is shown that the full discrete scheme possesses convergence rates of order h γ in space and order τ γ 2 in time, subject to the spatial correlation of the noise process, characterized by AIn particular, a classical convergence rate of order O(h 2 + τ ) is reachable, even in multiple spatial dimensions, when the aforementioned condition is fulfilled with γ = 2. Numerical examples confirm the previous findings.Here · L 2 stands for the Hilbert-Schmidt norm,Ḣ α := D(A α 2 ), α ∈ R and the parameter γ ∈ [1, 2] coming from (1.2) quantifies the spatial regularity of the covariance operator Q of the

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Infinite-Dimensional Stochastic Hamiltonian Systems

Hong

Sun

2022

Lecture Notes in Mathematics

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Strong convergence rates for nonlinearity-truncated Euler-type approximations of stochastic Ginzburg–Landau equations

Cited by 55 publications

References 57 publications

Strong convergence rates of semidiscrete splitting approximations for the stochastic Allen–Cahn equation

Strong convergence rates of semidiscrete splitting approximations for the stochastic Allen–Cahn equation

Optimal Error Estimates of Galerkin Finite Element Methods for Stochastic Allen–Cahn Equation with Additive Noise

Infinite-Dimensional Stochastic Hamiltonian Systems

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