Title :
Weighted Laguerre polynomials-discrete singular convolution method for efficient solution of maxwell´s equations
Author :
Zhao, Huapeng ; Shen, Zhongxiang
Author_Institution :
Sch. of Electr. & Electron. Eng., Nanyang Technol. Univ., Singapore, Singapore
Abstract :
This paper presents a three-dimensional weighted Laguerre polynomials-discrete singular convolution (WLP-DSC) method for efficient and unconditionally stable solution of time-domain Maxwell´s equations in lossy media. In the proposed WLP-DSC method, temporal variations of fields are first expanded with the orthogonal and global WLP bases and a Galerkin´s matching process is then invoked upon time-domain Maxwell´s equations to eliminate the time variable, through which a marching on in degree scheme is obtained. Spatial derivatives are then approximated with a high-order DSC method. Adopting low spatial sampling density in the DSC method, computational burden is greatly reduced with the proposed method. Comparisons with conventional WLP-finite difference method are presented to demonstrate the validity and advantages of our proposed method.
Keywords :
Galerkin method; Maxwell equations; finite difference time-domain analysis; polynomials; stochastic processes; Galerkin matching process; WLP-finite difference method; lossy media; spatial sampling density; three-dimensional polynomials-discrete singular convolution method; time-domain Maxwell equations; weighted Laguerre polynomials-discrete singular convolution method; Computational efficiency; Convolution; Costs; Finite difference methods; Matrix decomposition; Maxwell equations; Moment methods; Polynomials; Stability; Time domain analysis; Discrete singular convolution method; transient analysis; weighted Laguerre polynomials;
Conference_Titel :
Microwave Conference, 2009. APMC 2009. Asia Pacific
Conference_Location :
Singapore
Print_ISBN :
978-1-4244-2801-4
Electronic_ISBN :
978-1-4244-2802-1
DOI :
10.1109/APMC.2009.5384280
