An implicit characteristic-based approach for numerical solution of Maxwell's time-dependent curl equations in flux conservative form is introduced. This method combines a characteristic based finite difference spatial approximation with an implicit lower-upper approximate factorization (LU/AF) time integration scheme. This approach is advantageous for three-dimensional applications because the characteristic differencing enables a two-factor approximate factorization that retains its unconditional stability in three space dimensions, and it does not require solution of tridiagonal systems. Results are given both for a Fourier analysis of stability, damping and dispersion properties, and for one-dimensional model problems involving propagat...
Existing numerical methods for the solution of the time domain Maxwell equations often rely on expli...
In this chapter, we present three main numerical methods that are capa ble of solving complex electr...
International audienceThe time-harmonic Maxwell equations describe the propagation of electromagneti...
This thesis proposes several new finite-difference time-domain (FDTD) methods to overcome shortcomin...
There has been some recent work to develop two and three-dimensional alternating direction implicit ...
Characteristic-based finite-difference and finite-volume schemes have been developed for solving the...
Explicit FDTD method is one of the most popular methods for time domain analysis because it does not...
Numerical procedures for solving the time-domain Maxwell equations based on the theory of characteri...
In this thesis, the alternating-direction implicit method (ADI) is investigated in conjunction with ...
We present a comparative study of numerical algorithms to solve the time-dependent Maxwell equations...
We consider the time dependent Maxwell’s equations in dispersive media on a bounded domain in three-...
Abstract: The finite-difference time-domain (FDTD) method is an explicit time discretization scheme ...
The most commonly used method for the time-domain Maxwell equations is the Finite-Difference Time-Do...
Characteristic-based finite-difference and finite-volume schemes have been developed for solving the...
The finite-difference time-domain (FDTD) method has been widely applied in solving electromagnetic p...
Existing numerical methods for the solution of the time domain Maxwell equations often rely on expli...
In this chapter, we present three main numerical methods that are capa ble of solving complex electr...
International audienceThe time-harmonic Maxwell equations describe the propagation of electromagneti...
This thesis proposes several new finite-difference time-domain (FDTD) methods to overcome shortcomin...
There has been some recent work to develop two and three-dimensional alternating direction implicit ...
Characteristic-based finite-difference and finite-volume schemes have been developed for solving the...
Explicit FDTD method is one of the most popular methods for time domain analysis because it does not...
Numerical procedures for solving the time-domain Maxwell equations based on the theory of characteri...
In this thesis, the alternating-direction implicit method (ADI) is investigated in conjunction with ...
We present a comparative study of numerical algorithms to solve the time-dependent Maxwell equations...
We consider the time dependent Maxwell’s equations in dispersive media on a bounded domain in three-...
Abstract: The finite-difference time-domain (FDTD) method is an explicit time discretization scheme ...
The most commonly used method for the time-domain Maxwell equations is the Finite-Difference Time-Do...
Characteristic-based finite-difference and finite-volume schemes have been developed for solving the...
The finite-difference time-domain (FDTD) method has been widely applied in solving electromagnetic p...
Existing numerical methods for the solution of the time domain Maxwell equations often rely on expli...
In this chapter, we present three main numerical methods that are capa ble of solving complex electr...
International audienceThe time-harmonic Maxwell equations describe the propagation of electromagneti...