Abstract
The computation of the augmented electric field integral equation (A-EFIE) is accelerated by using the multilevel complex source beam (MLCSB) method. As an effective solution of the low-frequency problem, A-EFIE includes both current and charge as unknowns to avoid the imbalance between the vector potentials and the scalar potentials in the conventional EFIE. However, dense impedance submatrices are involved in the A-EFIE system, and the computational cost becomes extremely high for problems with a large number of unknowns. As an exact solution to Maxwell’s equations, the complex source beam (CSB) method can be well tailored for A-EFIE to accelerate the matrix-vector products in an iterative solver. Different from the commonly used multilevel fast multipole algorithm (MLFMA), the CSB method is free from the problem of low-frequency breakdown. In our implementation, the expansion operators of CSB are first derived for the vector potentials and the scalar potentials. Consequently, the aggregation and disaggregation operators are introduced to form a multilevel algorithm to reduce the computational complexity. The accuracy and efficiency of the proposed method are discussed in detail through a variety of numerical examples. It is observed that the numerical error of the MLCSB-AEFIE keeps constant for a broad frequency range, indicating the good stability and scalability of the proposed method.
Highlights
The method of moments (MoM) [1] for solving electric field integral equation (EFIE) has received intensive study in the analysis of electromagnetic (EM) radiation, scattering, and circuit problems in recent years
Given a 3D perfectly electrical conducting (PEC) body defined by its surface, the conventional MoM formulation can be applied to the electric field integral equation (EFIE), leading to a matrix equation of the form
In the augmented electric field integral equation, the surface current is discretized by the normalized RWG basis function, which is modified by removing the length of the common edge ρi (r)
Summary
The method of moments (MoM) [1] for solving electric field integral equation (EFIE) has received intensive study in the analysis of electromagnetic (EM) radiation, scattering, and circuit problems in recent years. Since the scalar potential term is singular, the EFIE matrix system becomes extremely ill-conditioned and results in convergence issue when the iterative solver is applied. To address this difficulty, several methods have been proposed in the past years. As the number of unknowns increases, a fast algorithm has to be incorporated into the iterative solver to reduce the operation complexity of the matrix-vector product (MVP). Since the CSBs are exact solutions of Maxwell’s equations, any arbitrary EM fields can be expanded in terms of a set of CSBs [20, 24] This method can be extended to solve the low-frequency problems without any theoretical barriers.
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