A new matrix method for solving two-dimensional time-dependent diffusion equations with Dirichlet boundary conditions
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摘要
This paper is devoted to develop a new matrix scheme for solving two-dimensional time-dependent diffusion equations with Dirichlet boundary conditions. We first transform these equations into equivalent integro partial differential equations (PDEs). Such these integro-PDEs contain both of the initial and boundary conditions and can be solved numerically in a more appropriate manner. Subsequently, all the existing known and unknown functions in the latter equations are approximated by Bernoulli polynomials and operational matrices of differentiation and integration together with the completeness of these polynomials can be used to reduce the integro-PDEs into the associated algebraic generalized Sylvester equations. For solving these algebraic equations, an efficient Krylov subspace iterative method (i.e., BICGSTAB) is implemented. Two numerical examples are given to demonstrate the efficiency, accuracy, and versatility of the proposed method.
论文关键词:Two-dimensional diffusion equations,Dirichlet boundary conditions,Polynomial approximation,Bernoulli polynomials,Operational matrices
论文评审过程:Received 14 January 2016, Revised 20 May 2016, Accepted 13 June 2016, Available online 2 July 2016, Version of Record 2 July 2016.
论文官网地址:https://doi.org/10.1016/j.amc.2016.06.023