Electromagnetic Field Theory for Engineers and Physicists
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, magnetostatics, quasi stationary fields and electromagnetic fields.

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 are 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.

A book whose usefulness is not limited to engineering students, but can be very helpful for physicists and other branches of science.

1128881991
Electromagnetic Field Theory for Engineers and Physicists
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, magnetostatics, quasi stationary fields and electromagnetic fields.

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 are 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.

A book whose usefulness is not limited to engineering students, but can be very helpful for physicists and other branches of science.

89.99 In Stock
Electromagnetic Field Theory for Engineers and Physicists

Electromagnetic Field Theory for Engineers and Physicists

Electromagnetic Field Theory for Engineers and Physicists

Electromagnetic Field Theory for Engineers and Physicists

Overview

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, magnetostatics, quasi stationary fields and electromagnetic fields.

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 are 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.

A book whose usefulness is not limited to engineering students, but can be very helpful for physicists and other branches of science.

Product Details

ISBN-13: 9783642425295
Publisher: Springer Berlin Heidelberg
Publication date: 11/26/2014
Edition description: 2010
Pages: 659
Product dimensions: 6.10(w) x 9.25(h) x 0.05(d)

About the Author

Günther Lehner,

Studied mathematics and physics and afterwards, from 1957 through 1972, he held positions at various places, at the Technical University of Munich (Germany), the Institute for Plasma Physics in Garching near Munich (Germany), the Laborario Gas Ionizzati of Frascati near Rome (Italy). He researched in the area of plasma physics, thermonuclear fusion (fusion reactor), and highest magnetic fields. In 1961 he received his Ph.D. in the field of plasma physics and in 1967 his habilitation on topics of highest magnetic fields from the Technical University of Munich. In 1972 he was called to the University of Stuttgart (Germany) to head the department of Theoretical Electrical Engineering, to research and teach topics covering electromagnetic fields, energy conversion, and use of alternative energy sources, solar energy in particular. Emeritus in 1996.

Table of Contents

Maxwell#x2019;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.
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