A Linearly Implicit Structure-Preserving Scheme for the Camassa–Holm Equation Based on Multiple Scalar Auxiliary Variables Approach

Jiang, Chenglong; Gong, Yuezheng; Cai, Wenjun; Wang, Yushun

doi:10.1007/s10915-020-01201-4

Cited by 23 publications

(6 citation statements)

References 26 publications

(28 reference statements)

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“…Recently, more work has been put into developing linearly implicit energy-preserving schemes for Hamiltonian PDEs, e.g. the partitioned averaged vector field (PAVF) method [25] and schemes based on the invariant energy quadratization (IEQ) approach [26] or the multiple scalar auxiliary variables (MSAV) approach [27]. However, little attention has been given to linearly implicit local energy-preserving methods.…”

Section: Introductionmentioning

confidence: 99%

Linearly implicit structure-preserving schemes for Hamiltonian systems

Eidnes¹,

Li²,

Sato

2021

Journal of Computational and Applied Mathematics

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We present linearly implicit methods that preserve discrete approximations to local and global energy conservation laws for multi-symplectic PDEs with cubic invariants. The methods are tested on the one-dimensional Korteweg-de Vries equation and the two-dimensional Zakharov-Kuznetsov equation; the numerical simulations confirm the conservative properties of the methods, and demonstrate their good stability properties and superior running speed when compared to fully implicit schemes.

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Section: Introductionmentioning

confidence: 99%

Linearly implicit structure-preserving schemes for Hamiltonian systems

Eidnes¹,

Li²,

Sato

2021

Journal of Computational and Applied Mathematics

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“…Due to its attractive properties, the SAV approach has been intensively studied in these years. It has been applied to many PDEs, for example, the two-dimensional sine-Gordon equation [6], the fractional nonlinear Schrödinger equation [12], the Camassa-Holm equation [21], and the imaginary time gradient flow [42]. Shen and Xu [32] and Li, Shen and Rui [22] conducted a convergence analysis of SAV schemes.…”

Section: Introductionmentioning

confidence: 99%

Scalar auxiliary variable approach for conservative/dissipative partial differential equations with unbounded energy

Kemmochi¹,

Sato²

2021

Preprint

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In this paper, we present a novel investigation of the so-called SAV approach, which is a framework to construct linearly implicit geometric numerical integrators for partial differential equations with variational structure. SAV approach was originally proposed for the gradient flows that have lower-bounded nonlinear potentials such as the Allen-Cahn and Cahn-Hilliard equations, and this assumption on the energy was essential. In this paper, we propose a novel approach to address gradient flows with unbounded energy such as the KdV equation by a decomposition of energy functionals. Further, we will show that the equation of the SAV approach, which is a system of equations with scalar auxiliary variables, is expressed as another gradient system that inherits the variational structure of the original system. This expression allows us to construct novel higher-order integrators by a certain class of Runge-Kutta methods. We will propose second and fourth order schemes for conservative systems in our framework and present several numerical examples.

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“…One systematical methodology to construct linearly implicit schemes for general systems is the energy quadratization technique, which includes the invariant energy quadratization (IEQ) approach [45,46,21] and the scalar auxiliary variable (SAV) approach [40,39]. Although the energy quadratization technique is originally proposed for dissipative gradient flow models, it has also been applied to Hamiltonian systems [8,7,28,30], but no multi-components systems have been concerned so far. One main reason that restricts the further applications may be attributed to the preservation of so-called modified energy, and continuous efforts are still made to improve this shortage [11].…”

Section: Introductionmentioning

confidence: 99%

Efficient energy-preserving exponential integrators for multi-components Hamiltonian systems

Gu¹,

Jiang²,

Wang³

et al. 2021

Preprint

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In this paper, we develop a framework to construct energy-preserving methods for multi-components Hamiltonian systems, combining the exponential integrator and the partitioned averaged vector field method. This leads to numerical schemes with both advantages of long-time stability and excellent behavior for highly oscillatory or stiff problems. Compared to the existing energy-preserving exponential integrators (EP-EI) in practical implementation, our proposed methods are much efficient which can at least be computed by subsystem instead of handling a nonlinear coupling system at a time. Moreover, for most cases, such as the Klein-Gordon-Schrödinger equations and the Klein-Gordon-Zakharov equations considered in this paper, the computational cost can be further reduced. Specifically, one part of the derived schemes is totally explicit, and the other is linearly implicit. In addition, we present rigorous proof of conserving the original energy of Hamiltonian systems, in which an alternative technique is utilized so that no additional assumptions are required, in contrast to the proof strategies used for the existing EP-EI. Numerical experiments are provided to demonstrate the significant advantages in accuracy, computational efficiency, and the ability to capture highly oscillatory solutions.

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A Linearly Implicit Structure-Preserving Scheme for the Camassa–Holm Equation Based on Multiple Scalar Auxiliary Variables Approach

Cited by 23 publications

References 26 publications

Linearly implicit structure-preserving schemes for Hamiltonian systems

Linearly implicit structure-preserving schemes for Hamiltonian systems

Scalar auxiliary variable approach for conservative/dissipative partial differential equations with unbounded energy

Efficient energy-preserving exponential integrators for multi-components Hamiltonian systems

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