Two exponential-type integrators for the “good” Boussinesq equation

Ostermann, Alexander; Su, Chunmei

doi:10.1007/s00211-019-01064-4

Cited by 22 publications

(14 citation statements)

References 36 publications

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“…The goal of this section is to construct a first order discretization of the oscillatory integral (14) when working on a general domain Ω, and which allows for the improved local error structure (15) established in the preceding section. This is achieved by introducing a properly chosen filtered function which will filter out the dominant oscillatory terms L dom,1 , L dom,2 explicitely found in the preceding section.…”

Section: General Boundary Conditions: ω ⊂ R Dmentioning

confidence: 99%

“…Hence, we recover the discretization of the oscillatory integral (14) together with an improved local error structure of the form (15);…”

Section: General Boundary Conditions: ω ⊂ R Dmentioning

confidence: 99%

“…Recently much progress has been made in the development of low-regularity approximations to nonlinear evolution equations. First, in the case of periodic boundary conditions a class of schemes called Fourier integrators [12] or resonance based schemes [4] were introduced to approximate the time dynamics of dispersive equations such as NLS, KdV, Boussinesq, Dirac and Klein-Gordon (see [8], [11], [14] , [17], [5]). Very recently higher order extensions of these resonance based schemes were introduced in [4] for approximating in a unified fashion a large class of dispersive equations with periodic boundary conditions.…”

Section: Introductionmentioning

confidence: 99%

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Error analysis of a class of semi-discrete schemes for solving the Gross-Pitaevskii equation at low regularity

Bronsard

2022

Preprint

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We analyse a class of time discretizations for solving the Gross-Pitaevskii equation at low-regularity on an arbitrary Lipschitz domain Ω ⊂ R d , d ≤ 3, with a non-smooth potential. We show that these schemes, together with their optimal local error structure, allow for convergence under lower regularity assumptions on both the solution and the potential than is required by classical methods, such as splitting or exponential integrator methods. Moreover, we show convergence in the case of periodic boundary conditions, in any fractional positive Sobolev space H r , r ≥ 0 beyond the more typical L 2 -error analysis.

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Section: General Boundary Conditions: ω ⊂ R Dmentioning

confidence: 99%

“…Hence, we recover the discretization of the oscillatory integral (14) together with an improved local error structure of the form (15);…”

Section: General Boundary Conditions: ω ⊂ R Dmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Error analysis of a class of semi-discrete schemes for solving the Gross-Pitaevskii equation at low regularity

Bronsard

2022

Preprint

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“…While first-order resonance-based discretisations have been presented for particular examples – for example, the Nonlinear Schrödinger (NLS), Korteweg–de Vries (KdV), Boussinesq, Dirac and Klein–Gordon equation; see [50, 4, 5, 72, 73, 76] – no general framework could be established so far. Each and every equation had to be targeted carefully one at a time based on a sophisticated resonance analysis.…”

Section: Introductionmentioning

confidence: 99%

Resonance-based schemes for dispersive equations via decorated trees

Bruned

Schratz

2022

Forum of Mathematics, Pi

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We introduce a numerical framework for dispersive equations embedding their underlying resonance structure into the discretisation. This will allow us to resolve the nonlinear oscillations of the partial differential equation (PDE) and to approximate with high-order accuracy a large class of equations under lower regularity assumptions than classical techniques require. The key idea to control the nonlinear frequency interactions in the system up to arbitrary high order thereby lies in a tailored decorated tree formalism. Our algebraic structures are close to the ones developed for singular stochastic PDEs (SPDEs) with regularity structures. We adapt them to the context of dispersive PDEs by using a novel class of decorations which encode the dominant frequencies. The structure proposed in this article is new and gives a variant of the Butcher–Connes–Kreimer Hopf algebra on decorated trees. We observe a similar Birkhoff type factorisation as in SPDEs and perturbative quantum field theory. This factorisation allows us to single out oscillations and to optimise the local error by mapping it to the particular regularity of the solution. This use of the Birkhoff factorisation seems new in comparison to the literature. The field of singular SPDEs took advantage of numerical methods and renormalisation in perturbative quantum field theory by extending their structures via the adjunction of decorations and Taylor expansions. Now, through this work, numerical analysis is taking advantage of these extended structures and provides a new perspective on them.

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“…In more details, an unconditional full order convergence was shown for a second order operator splitting numerical scheme in the energy norm [33]: the H 2 × L 2 norm in z × z t . Nowadays, exponential time integrators have been widely applied for parabolic and hyperbolic equations [18,25,28,34]. Particularly, several efficient schemes were proposed for solving the GB equation [25] based on fourth-order exponential integrators of Runge-Kutta type.…”

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confidence: 99%

A Deuflhard-Type Exponential Integrator Fourier Pseudo-Spectral Method for the “Good” Boussinesq Equation

Yao

2020

J Sci Comput

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We propose an exponential integrator Fourier pseudospectral method DEI-FP for solving the "Good" Boussinesq (GB) equation. The numerical scheme is based on a Deuflhardtype exponential integrator and a Fourier pseudospectral method for temporal and spatial discretizations, respectively. The scheme is fully explicit and efficient due to the fast Fourier transform. Rigorous error estimates are established for the method without any CFL-type condition constraint. In more details, the method converges quadratically and spectrally in time and space, respectively. Extensive numerical experiments are reported to confirm the theoretical analysis and to demonstrate rich dynamics of the GB equation.

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Two exponential-type integrators for the “good” Boussinesq equation

Cited by 22 publications

References 36 publications

Error analysis of a class of semi-discrete schemes for solving the Gross-Pitaevskii equation at low regularity

Error analysis of a class of semi-discrete schemes for solving the Gross-Pitaevskii equation at low regularity

Resonance-based schemes for dispersive equations via decorated trees

A Deuflhard-Type Exponential Integrator Fourier Pseudo-Spectral Method for the “Good” Boussinesq Equation

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