Title :
Nodal-based finite-element modeling of Maxwell´s equations
Author :
Boyse, William E. ; Lynch, Daniel R. ; Paulsen, Keith D. ; Minerbo, Gerald N.
Author_Institution :
Lockheed Missiles & Space Co., Palo Alto, CA, USA
fDate :
6/1/1992 12:00:00 AM
Abstract :
Weak forms are derived for Maxwell´s equations which are suitable for implementation on conventional C0 elements with scalar bases. The governing equations are expressed in terms of general vector and scalar potentials for the electric field intensity vector. Gauge theory is invoked to close the system and dictates the continuity requirements for the potentials at material interfaces as well as the blend of boundary conditions at exterior boundaries. Two specific gauges are presented, both of which lead to Helmholtz weak forms which are parasite-free and enjoy simple, physically meaningful boundary conditions. A general and numerically efficient procedure for enforcing the jump discontinuities on the normal components of vector fields at dielectric interfaces and boundary conditions on curved surfaces is also given
Keywords :
boundary-value problems; electromagnetic field theory; electromagnetic wave propagation; finite element analysis; Helmholtz weak forms; Maxwell´s equations; boundary conditions; curved surfaces; dielectric interfaces; electric field intensity vector; electromagnetic propagation; electromagnetics; exterior boundaries; finite-element modeling; gauge theory; governing equations; jump discontinuities; nodal-based modelling; scalar potentials; vector potentials; Boundary conditions; Boundary value problems; Dielectrics; Displays; Eigenvalues and eigenfunctions; Electromagnetic fields; Finite element methods; Magnetic materials; Maxwell equations; Missiles;
Journal_Title :
Antennas and Propagation, IEEE Transactions on
