Time domain modeling of pulse propagation in non-isotropic dispersive media

## Abstract A time‐domain solution of electromagnetic wave propagation in Tellegen materials is presented. The angle tilt between electric and magnetic fields, the phase speed of the wave, and the intrinsic impedance are computed when the medium is excited with a monochromatic source. The results a

## Abstract The work of Barba et al.1 is fatally flawed on two counts: (i) the existence of Tellegen mediums is unrecognizable in modern electromagnetic theory, and (ii) the time‐domain constitutive relations used in the commented upon work are noncausal. © 2004 Wiley Periodicals, Inc. Microwave Op

## Abstract Accurate modeling of pulse propagation and scattering is a problem in many disciplines (i.e., electromagnetics and acoustics). It is even more tenuous when the medium is dispersive. Blackstock [D. T. Blackstock, J Acoust Soc Am 77 (1985) 2050] first proposed a theory that resulted in ad

## Abstract Non‐local dispersive model for wave propagation in heterogeneous media is derived from the higher‐order mathematical homogenization theory with multiple spatial and temporal scales. In addition to the usual space–time co‐ordinates, a fast spatial scale and a slow temporal scale are intr

## Abstract Three non‐dispersive models in multi‐dimensions have been developed. The first model consists of a leading‐order homogenized equation of motion subjected to the secularity constraints imposing uniform validity of asymptotic expansions. The second, non‐local model, contains a fourth‐orde