Time discretizations for Maxwell-Bloch equations

We have constructed reliable finite difference methods for approximating the solution to Maxwell's equations using accurate discrete analogs of differential operators that satisfy the identities and theorems of vector and tensor calculus in discrete form. The numerical approximation does not have sp

## Abstract We introduce a new preconditioning technique for iteratively solving linear systems arising from finite element discretization of the mixed formulation of the time‐harmonic Maxwell equations. The preconditioners are motivated by spectral equivalence properties of the discrete operators,

which might be constant in many practical problems. Ͳ is a positive constant and Ͳ Ͻ 1. F is a positive constant which A finite difference scheme is proposed for solving the initialboundary value problem of the Maxwell-Bloch equations. Its nu-measures the number of modes that can oscillate in the re

Many results have been obtained in the past decade about the justification of nonlinear geometric optics expansions (see references below and the survey papers [JMR1, JMR2]). All of them consider general equations and make no assumption on the structure of the nonlinear terms. There are cases where

The generalized Bloch equations in the rotating frame are solved in Cartesian space by an approach that is different from the earlier Torrey solutions. The solutions are cast into a compact and convenient matrix notation, which paves the way for a direct physical insight and comprehension of the evo