Detail publikace

Modeling of Nonuniform Multiconductor Transmission Lines via Wendroff Method

BRANČÍK, L. ŠEVČÍK, B.

Originální název

Modeling of Nonuniform Multiconductor Transmission Lines via Wendroff Method

Typ

článek ve sborníku ve WoS nebo Scopus

Jazyk

angličtina

Originální abstrakt

The paper deals with a technique of the time-domain modeling of nonuniform multiconductor transmission lines (MTL) based on an implicit Wendroff method. This technique falls into a class of the finite-difference time-domain (FDTD) methods useful to solve various electromagnetic systems. Its basic version is extended to enable solving both voltage and/or current distributions along the MTL's wires and their sensitivities with respect to lumped and distributed parameters. Experimental error analysis is performed based on the Thomson cable, a single transmission line with known analytical solutions. The examples of simulation of both uniform and nonuniform MTLs are shown and compared with other methods, first results for nonlinear MTLs are also presented. All computations were performed in the Matlab language environment while utilizing sparse matrix notations to enable effective and fast solution.

Klíčová slova

Nonuniform multiconductor transmission line; sensitivity analysis; time-domain modeling; Wendroff method

Autoři

BRANČÍK, L.; ŠEVČÍK, B.

Rok RIV

2010

Vydáno

30. 11. 2010

Místo

Puerto De La Cruz, Tenerife, Canary Islands, Spain

ISBN

978-960-474-252-3

Kniha

Proceedings of the International Conference on Mathematical Models for Engineering Science (MMES 10)

Strany od

130

Strany do

133

Strany počet

4

BibTex

@inproceedings{BUT34888,
  author="Lubomír {Brančík} and Břetislav {Ševčík}",
  title="Modeling of Nonuniform Multiconductor Transmission Lines via Wendroff Method",
  booktitle="Proceedings of the International Conference on Mathematical Models for Engineering Science (MMES 10)",
  year="2010",
  pages="130--133",
  address="Puerto De La Cruz, Tenerife, Canary Islands, Spain",
  isbn="978-960-474-252-3"
}