Multifrontal method preconditioned GMRES‐FFT algorithm for fast analysis of microstrip circuits

## Abstract In this paper, the multifrontal method is employed to precondition the conjugate gradient (CG) algorithm with the block Toeplitz matrix based fast Fourier transform (FFT) technique for dense matrix equations from the mixed potential integral equation (MPIE) to enhance the computational

In this article, the microstrip circuit is analyzed in terms of the mixed-potential integral equation (MPIE) by means of the rooftop-function expansion and the blaze-function testing technique, and the integral equation is solved using the loose generalized minimal residual fast Fourier transform (L

## Abstract In this paper, the wavelet transform technique is used to transform dense matrix equations from the mixed potential integral equation (MPIE) to obtain sparse matrix equations, after dropping elements smaller than the threshold. The multifrontal method is employed to solve the resultant

## Abstract In this paper, the microstrip circuit is analyzed in terms of the mixed potential integral equation (MPIE) by using the rooftop‐function expansion and the blaze‐function testing technique. The integral equation is solved by the inner‐outer flexible generalized minimal residual fast Four

## Abstract In this Letter, the inexact preconditioned conjugate‐gradient (CG) algorithm with inner–outer iteration and the block‐Toeplitz‐matrix–based fast–Fourier‐ transform (FFT) technique are applied to dense matrix equations from the mixed potential integral equation (MPIE) to enhance the comp

## Abstract The increase of the time step size significantly deteriorates the property of the coefficient matrix generated from the Crank‐Nicolson finite‐difference time‐domain (CN‐FDTD) method. As a result, the convergence of classical iterative methods, such as generalized minimal residual method