A matrix-oriented POD-DEIM algorithm applied to semilinear matrix differential equations

Abstract

We are interested in numerically approximating the solution U(t) of the large dimensional semilinear matrix differential equation U(t) = A U(t) + U(t) B + F( U,t), with appropriate starting and boundary conditions, and t ∈ [0, Tf]. In the framework of the Proper Orthogonal Decomposition (POD) methodology and the Discrete Empirical Interpolation Method (DEIM), we derive a novel matrix-oriented reduction process leading to an effective, structure aware low order approximation of the original problem. The reduction of the nonlinear term is also performed by means of a fully matricial interpolation using left and right projections onto two distinct reduction spaces, giving rise to a new two-sided version of DEIM. By maintaining a matrix-oriented reduction, we are able to employ first order exponential integrators at negligible costs. Numerical experiments on benchmark problems illustrate the effectiveness of the new setting.