Notice bibliographique
- Notice
Type(s) de contenu et mode(s) de consultation : Texte noté : électronique
Auteur(s) : Lehner, Günther
Titre(s) : Electromagnetic field theory for engineers and physicists [Texte électronique] / Günther Lehner ; translated by Matt Horrer
Publication : Heidelberg ; New York : Springer, cop. 2010
Description matérielle : 1 ressource dématérialisée
Note(s) : Translated from the German. - Includes bibliographical references and index
"This established, didactically excellent textbook unifies intuitiveness with extraordinary
precision of its terminology and the derivation of concepts. It was developed as manuscript
to teach students in electrical engineering, and has served to do so for thousands
of students over two decades. Discussed is the electromagnetic field theory and its
mathematical methods. Maxwell's equations are presented and explained. It follows
a detailed discussion of electrostatics, flux problems, magnetostatics, quasi stationary
fields, and electromagnetic waves. The author presents how to apply numerical methods
like finite differences, finite elements, boundary elements, image charge methods,
and Monte-Carlo methods to field theory problems. He offers an outlook on fundamental
issues in physics including quantum mechanics. Some of these issues concern still
unanswered questions. A chapter dedicated to the theory of special relativity, which
allows to simplify a number of field theory problems, complements this book. This
book's usefulness is not limited to engineering students, but can also be very helpful
for physicists and other branches of science."--Publisher's website
Sujet(s) : Champs électromagnétiques
Théorie électromagnétique
Indice(s) Dewey :
530.141 (23e éd.) = Théorie électromagnétique
Identifiants, prix et caractéristiques : ISBN 9783540763062
Identifiant de la notice : ark:/12148/cb446960309
Notice n° :
FRBNF44696030
(notice reprise d'un réservoir extérieur)
Table des matières : Maxwell's Equations ; Basics of Electrostatics ; Formal Methods of Electrostatics
; The Stationary Current Density Field ; Basics of Magnetostatics ; Time Dependent
Problems I (Quasi Stationary Approximation) ; Time Dependent Problems II (Electromagnetic
Waves) ; Numerical Methods.