On the time-domain transmission-line equations

The problem of a transmission line closed on a lumped nonlinear load is analyzed. The problem of obtaining the load reflection coefficient and equi¨alent impedance is addressed and sol¨ed numerically for generic nonlinear loads and analytically for a diode.

Linear lossy two-conductor transmission line can be modelled as dynamic two ports in the time domain, via the describing input and transfer impulse responses. This convolution technique is very e!ective when dealing with networks composed of transmission lines with frequency-dependent parameters and

Asymptotic and exact local radiation boundary conditions (RBC) for the scalar time-dependent wave equation, ÿrst derived by Hagstrom and Hariharan, are reformulated as an auxiliary Cauchy problem for each radial harmonic on a spherical boundary. The reformulation is based on the hierarchy of local b

By virtue of the success of the transmission line matrix method (TLM) in solving heat and matter diffusion problems, it should also be applicable to the time-dependent Schrodinger equation. The occurrence of complexvalued circuit elements does not destroy the unconditional stability of the routine.

trated by examples. In the GTD-based model, only nine possible discrete values are used to describe the frequency dependence of the scattering center. Consequently, instead of continuous searching of the frequency-dependence parameters ␣ with the use of an iterative approach, which is quite m consum