Title :
A Low-Frequency Approximation to the Maxwell Equations Simultaneously Considering Inductive and Capacitive Phenomena
Author :
Koch, Stephan ; Schneider, Hermann ; Weiland, Thomas
Author_Institution :
Inst. fur Theor. Elektromagn. Felder, Tech. Univ. Darmstadt, Darmstadt, Germany
Abstract :
For many technical examples, low-frequency approximations to the full set of the Maxwell equations are applicable. Commonly, either the displacement current density or the induced current density are neglected depending on a priori knowledge about the dominating effects for a specific problem setup. This leads to different subsets of the Maxwell equations describing inductive-resistive or capacitive-resistive systems, respectively. In this paper, a formulation combining both scenarios while maintaining the quasistationary assumption, i.e., without modeling wave propagation and radiation, is presented. The formulation is applied to a simple test model consisting of a bounded massive conductor embedded in a dielectric insulation.
Keywords :
Maxwell equations; computational electromagnetics; finite element analysis; Maxwell equations; bounded massive conductor; displacement current density; finite element method; induced current density; low-frequency approximation; Approximation methods; Conductors; Current density; Electric potential; Magnetic domains; Mathematical model; Maxwell equations; Finite element method; Maxwell equations; frequency domain formulation; low-frequency approximation; quasistatic fields;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2011.2173163
