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Geometric Two-Scale Integrators for Highly Oscillatory System: Uniform Accuracy and Near Conservations

Bin Wang, Xiaofei Zhao

2023SIAM Journal on Numerical Analysis20 citationsDOI

Abstract

In this paper, we consider a class of highly oscillatory Hamiltonian systems which involve a scaling parameter . The problem arises from many physical models in some limit parameter regime or from some time-compressed perturbation problems. The solution of the model exhibits rapid temporal oscillations with -amplitude and -frequency, which makes classical numerical methods inefficient. We apply the two-scale formulation approach to the problem and propose two new time-symmetric numerical integrators. The methods are proved to have the uniform second order accuracy for all at finite times and some near-conservation laws in long times. Numerical experiments on a Hénon–Heiles model, two nonlinear Schrödinger equations, and a charged-particle system illustrate the performance of the proposed methods over the existing ones.

Topics & Concepts

IntegratorMathematicsNonlinear systemScalingHamiltonian systemAmplitudeHamiltonian (control theory)Conservation lawApplied mathematicsMathematical analysisNumerical analysisPartial differential equationMathematical optimizationPhysicsGeometryComputer scienceBandwidth (computing)Computer networkQuantum mechanicsNumerical methods for differential equationsComputational Fluid Dynamics and AerodynamicsDifferential Equations and Numerical Methods
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