Detail publikace

Broadband analysis of microwave structures by enhanced finite-element methods

Originální název

Broadband analysis of microwave structures by enhanced finite-element methods

Anglický název

Broadband analysis of microwave structures by enhanced finite-element methods

Jazyk

en

Originální abstrakt

The paper deals with the broadband modeling of microwave structures by finite-element methods. The attention is turned to original enhancements of accuracy, efficiency and stability of finite-element codes. The partial improvements are based on novel approximations both in the spatial domain and in the time one, in the adoption of complex frequency hopping, fast frequency sweep and envelope finite-element techniques. In the paper, a possible hybridization of approaches is discussed. Proposed finite-element schemes are applied to the analysis of canonical longitudinally homogeneous transmission lines in order to demonstrate their advantages.

Anglický abstrakt

The paper deals with the broadband modeling of microwave structures by finite-element methods. The attention is turned to original enhancements of accuracy, efficiency and stability of finite-element codes. The partial improvements are based on novel approximations both in the spatial domain and in the time one, in the adoption of complex frequency hopping, fast frequency sweep and envelope finite-element techniques. In the paper, a possible hybridization of approaches is discussed. Proposed finite-element schemes are applied to the analysis of canonical longitudinally homogeneous transmission lines in order to demonstrate their advantages.

Dokumenty

BibTex


@article{BUT42710,
  author="Milan {Motl} and Zbyněk {Raida}",
  title="Broadband analysis of microwave structures by enhanced finite-element methods",
  annote="The paper deals with the broadband modeling of microwave structures by finite-element methods. The attention is turned to original enhancements of accuracy, efficiency and stability of finite-element codes. The partial improvements are based on novel approximations both in the spatial domain and in the time one, in the adoption of complex frequency  hopping, fast frequency sweep and envelope finite-element techniques. In the paper, a possible hybridization of approaches is discussed. Proposed finite-element schemes are applied to the analysis
of canonical longitudinally homogeneous transmission
lines in order to demonstrate their advantages.",
  chapter="42710",
  journal="Radioengineering",
  number="4",
  volume="14",
  year="2005",
  month="november",
  pages="48",
  type="journal article - other"
}