Litcius/Paper detail

Moment Preserving Fourier–Galerkin Spectral Methods and Application to the Boltzmann Equation

Lorenzo Pareschi, Thomas Rey

2022SIAM Journal on Numerical Analysis15 citationsDOIOpen Access PDF

Abstract

Spectral methods, thanks to the high accuracy and the possibility of using fast algorithms, represent an effective way to approximate collisional kinetic equations in kinetic theory. On the other hand, the loss of some local invariants can lead to the wrong long time behavior of the numerical solution. We introduce in this paper a novel Fourier-Galerkin spectral method that improves the classical spectral method by making it conservative on the moments of the approximated distribution, without sacrificing its spectral accuracy or the possibility of using fast algorithms. The method is derived directly using a constrained best approximation in the space of trigonometric polynomials and can be applied to a wide class of problems where preservation of moments is essential. We then apply the new spectral method to the evaluation of the Boltzmann collision term, and prove spectral consistency and stability of the resulting Fourier-Galerkin approximation scheme. Various numerical experiments illustrate the theoretical findings.

Topics & Concepts

Spectral methodMathematicsBoltzmann equationGalerkin methodFourier transformStability (learning theory)Method of moments (probability theory)Mathematical analysisMoment (physics)Applied mathematicsAlgorithmComputer scienceClassical mechanicsPhysicsFinite element methodEstimatorMachine learningThermodynamicsQuantum mechanicsStatisticsGas Dynamics and Kinetic TheoryRadiative Heat Transfer StudiesCombustion and flame dynamics
Moment Preserving Fourier–Galerkin Spectral Methods and Application to the Boltzmann Equation | Litcius