Lagrangian formulation of electromagnetic fields in nondispersive medium by means of the extended Euler-Lagrange differential equation
Loading...
Date
2008
Authors
Journal Title
Journal ISSN
Volume Title
Publisher
Pergamon-Elsevier Science Ltd
Open Access Color
Green Open Access
Yes
OpenAIRE Downloads
OpenAIRE Views
Publicly Funded
No
BIP! Indicators
Impulse
Average
Influence
Top 10%
Popularity
Average
Abstract
This work is concerned with the Lagrangian formulation of electromagnetic fields. Here the extended Euler-Lagrange differential equation for continuous nondispersive media is employed. The Lagrangian density for electromagnetic fields is extended to derive all four Maxwell's equations by means of electric and magnetic potentials. For the first time ohmic losses for time and space variant fields are included. Therefore a dissipation density function with time dependent and gradient dependent terms is developed. Both the Lagrangian density and the dissipation density functions obey the extended Euler-Lagrange differential equation. Finally two examples demonstrate the advantage of describing interacting physical systems by a single Lagrangian density. © 2008 Elsevier Ltd. All rights reserved. © 2008 Elsevier B.V. All rights reserved.
Description
Keywords
Electromagnetic Potentials, Euler-lagrange Differential Equation, Lagrangian Density, Maxwell's Equations, Electric Fields, Electromagnetic Field Measurement, Electromagnetic Fields, Electromagnetic Waves, Electromagnetism, Euler Equations, Lagrange Multipliers, Magnetic Materials, Probability Density Function, Density Functions, Electromagnetic Potentials, Euler-lagrange Differential Equation, Lag Ranges, Lagrangian Densities, Lagrangian Density, Lagrangian Formulations, Magnetic Potentials, Maxwell's Equations, Ohmic Losses, Physical Systems, Time Dependents, Maxwell Equations, Electric fields, Electromagnetic field measurement, Electromagnetic fields, Electromagnetic waves, Electromagnetism, Euler equations, Lagrange multipliers, Magnetic materials, Probability density function, Density functions, Electromagnetic potentials, Euler-Lagrange differential equation, Lag ranges, Lagrangian densities, Lagrangian density, Lagrangian formulations, Magnetic potentials, Maxwell's equations, Ohmic losses, Physical systems, Time dependents, Maxwell equations, Electromagnetic Potentials, Euler-Lagrange Differential Equation, Maxwell’s Equations, Lagrangian Density, Maxwell's equations, Electromagnetic theory (general), Euler-Lagrange differential equation, Lagrangian density, electromagnetic potentials
Fields of Science
0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, 02 engineering and technology, 01 natural sciences
Citation
WoS Q
Scopus Q
OpenCitations Citation Count
7
Source
International Journal of Engineering Science
Volume
46
Issue
12
Start Page
1218
End Page
1227
PlumX Metrics
Citations
CrossRef : 3
Scopus : 9
Captures
Mendeley Readers : 16
SCOPUS™ Citations
9
checked on Apr 09, 2026
Web of Science™ Citations
6
checked on Apr 09, 2026
Google Scholar™
