Detail publikace

Two-Dimensional Laplace Transformation in Linear Circuit Simulation

BRANČÍK, L.

Originální název

Two-Dimensional Laplace Transformation in Linear Circuit Simulation

Typ

článek ve sborníku ve WoS nebo Scopus

Jazyk

angličtina

Originální abstrakt

In the paper an unconventional method of a simulation of linear lumped–distributed circuits based on a Laplace transformation in two variables is discussed. Distributed parts are formed by uniform multiconductor transmission lines (MTL). Essentially two partial Laplace transformations are performed, with respect to the time t and coordinate x, to transform MTLs‘ partial differential equations into the algebraic ones. Considering further boundary conditions a two-dimensional transform in the (q,s)-domain is derived. Finally a method of the numerical inversion of 2D Laplace transforms is used to obtain the solution in the (x,t)-domain. Unlike previous works where generalized Thevenin/Norton equivalents have been used here modified nodal admittance equation method (MNA) is applied to incorporate the boundary conditions into a solution. By this arbitrarily complex circuits can be taken into account. Using universal scientific language Matlab voltage and/or current wave propagations along MTLs’ wires can effectively be stated and visualized.

Klíčová slova

Two-dimensional Laplace transformation, numerical inversion, distributed circuit, Matlab

Autoři

BRANČÍK, L.

Rok RIV

2003

Vydáno

6. 7. 2003

Místo

Warsaw

ISBN

83-916444-1-3

Kniha

Proceedings of ISTET´03, XII. International Symposium on Theoretical Electrical Engineering

Edice

Vol. 1

Číslo edice

1.

Strany od

101

Strany do

104

Strany počet

4

BibTex

@inproceedings{BUT9374,
  author="Lubomír {Brančík}",
  title="Two-Dimensional Laplace Transformation in Linear Circuit Simulation",
  booktitle="Proceedings of ISTET´03, XII. International Symposium on Theoretical Electrical Engineering",
  year="2003",
  series="Vol. 1",
  number="1.",
  pages="4",
  address="Warsaw",
  isbn="83-916444-1-3"
}