Thin-layer method: Formulation in the time domain

k simple physical picture is given of Fellncr-Feldegg's thin celi method in time dokin spectsoscapy. From this pic!ure an accurate analytical relstion is derived for the total reflection coefficient.

## Abstract A novel thin wire formulation for the description of thin wires in coarse numerical models is described. This new approach uses the exact local field expansions around the thin wire which are mapped onto the coarse mesh. The method is accurate, overcomes existing limitations and approxi

A simple relation, \xhich gives the permtttivity ztn~l~ticdly. is derived to approximate the transcendenta equation in the totaf transmission method in dielectric time domain spectroscopy\_ The limits for the appliubility of the method are dis-cussed\_ Results are given for I-butsnol and 3-propanoL

## Abstract A subcell model for arbitrarily located thin wires in the finite‐element time‐domain (FETD) method using modified telegraphers equations has been developed by Edelvik __et al__. Recently a dual set of equations has been proposed for modelling of thin slots. In this paper, we show that u

## Abstract A method is presented to incorporate thin, lossy layers into a finite‐difference frequency‐domain model while retaining a coarse grid‐spacing. This approach significantly reduces computational effort. The new method is validated by a comparison with analytical solutions. © 2004 Wiley Pe