Author_Institution :
Dept. of Mech. & Nucl. Eng., Pennsylvania State Univ., University Park, PA, USA
Abstract :
First principles battery models, consisting of non linear coupled partial differential equations, are often difficult to discretize and reduce in order so that they can be used by systems engineers for design, estimation, prediction, and management. In this paper, six methods are used to dis cretize a benchmark electrolyte diffusion problem and their time and frequency response accuracy is determined as a function of discretization order. The Analytical Method (AM), Integral Method Approximation (IMA), Pade Approximation Method (PAM), Finite Element Method (FEM), Finite Difference Method (FDM) and Ritz Method (RM) are formulated for the benchmark problem and convergence speed and accuracy calculated. The PAM is the most efficient, producing 99.5% accurate results with only a 3rd order approximation. IMA, Ritz, AM, FEM, and FDM required 4, 6, 9, 14, and 27th order approximations, respectively, to achieve the same error.
Keywords :
approximation theory; finite difference methods; finite element analysis; partial differential equations; secondary cells; AM; FDM; FEM; IMA; PAM; RM; Ritz method; analytical method; battery systems modeling; benchmark electrolyte diffusion problem; discretization methods; discretization order; finite difference method; finite element method; frequency response accuracy; integral method approximation; nonlinear coupled partial differential equations; pade approximation method; Approximation methods; Batteries; Eigenvalues and eigenfunctions; Equations; Finite element methods; Mathematical model; Transfer functions; Numerical methods; convergence; diffusion equations;
