Second-order linear structure-preserving modified finite volume schemes for the regularized long-wave equation
This work provides efficient energy-preserving numerical methods for a nonlinear wave equation, which is important for long-time simulations in computational physics.
The authors developed second-order accurate modified finite volume schemes for the regularized long-wave equation that preserve energy conservation at the discrete level, including both fully implicit and linear-implicit variants. Numerical experiments confirm accurate solutions and energy preservation.
In this paper, based on the weak form of the Hamiltonian formulation of the regularized long-wave equation and a novel approach of transforming the original Hamiltonian energy into a quadratic functional, a fully implicit and three linear-implicit energy conservation numerical schemes are respectively proposed. The resulting numerical schemes are proved theoretically to satisfy the energy conservation law in the discrete level. Moreover, these linear-implicit schemes are efficient in practical computation because only a linear system need to be solved at each time step. The proposed schemes are both second order accurate in time and space. Numerical experiments are presented to show all the proposed schemes have satisfactory performance in providing accurate solution and the remarkable energy-preserving property.