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This book consists of contributions given in honor of Wolfgang J.R. Hoefer. Space and time discretizing time domain methods for electromagnetic full-wave simulation have emerged as key numerical methods in computational electromagnetics. Time domain methods are versatile and can be applied to the solution of a wide range of electromagnetic field problems. Computing the response of an electromagnetic structure to an impulsive excitation localized in space and time provides a comprehensive characterization of the electromagnetic properties of the structure in a wide frequency range. The most…mehr

Produktbeschreibung
This book consists of contributions given in honor of Wolfgang J.R. Hoefer. Space and time discretizing time domain methods for electromagnetic full-wave simulation have emerged as key numerical methods in computational electromagnetics. Time domain methods are versatile and can be applied to the solution of a wide range of electromagnetic field problems. Computing the response of an electromagnetic structure to an impulsive excitation localized in space and time provides a comprehensive characterization of the electromagnetic properties of the structure in a wide frequency range. The most important methods are the Finite Difference Time Domain (FDTD) and the Transmission Line Matrix (TLM) methods.

The contributions represent the state of the art in dealing with time domain methods in modern engineering electrodynamics for electromagnetic modeling in general, the Transmission Line Matrix (TLM) method, the application of network concepts to electromagnetic fieldmodeling, circuit and system applications and, finally, with broadband devices, systems and measurement techniques.
Autorenporträt
Dr.-Ing. Uwe Siart, Jahrgang 1969, studierte Elektrotechnik mit Schwerpunkt Kommunikationselektrotechnik an der Friedrich-Alexander-Universität Erlangen-Nürnberg. Danach wechselte er an die Technische Universität München, wo er seit seiner Promotion (2005) als Akademischer Rat am Lehrstuhl für Hochfrequenztechnik tätig ist. Dort gibt er Vorlesungen über Hochfrequenzschaltungen und nichtlineare Mikrowellenschaltkreise. Seine Forschungsgebiete sind Signalverarbeitung und statistische Elektrodynamik.