Symplectic Hamiltonian Hybridizable Discontinuous Galerkin Methods for Linearized Shallow Water Equations

TL;DR

This paper develops a symplectic hybridizable discontinuous Galerkin method for linearized shallow water equations, preserving Hamiltonian structure and energy conservation through an auxiliary variable formulation and symplectic time integration.

Contribution

It introduces a novel HDG scheme that maintains the Hamiltonian structure of the equations, ensuring energy conservation in the numerical approximation.

Findings

Optimal convergence rates for all variables.

Conservation of total energy demonstrated.

Effective preservation of physical quantities over time.

Abstract

This paper focuses on the numerical approximation of the linearized shallow water equations using hybridizable discontinuous Galerkin (HDG) methods, leveraging the Hamiltonian structure of the evolution system. First, we propose an equivalent formulation of the equations by introducing an auxiliary variable. Then, we discretize the space variables using HDG methods, resulting in a semi-discrete scheme that preserves a discrete version of the Hamiltonian structure. The use of an alternative formulation with the auxiliary variable is crucial for developing the HDG scheme that preserves this Hamiltonian structure. The resulting system is subsequently discretized in time using symplectic integrators, ensuring the energy conservation of the fully discrete scheme. We present numerical experiments that demonstrate optimal convergence rates for all variables and showcase the conservation of total energy, as well as the evolution of other physical quantities.