Title :
An unconditionally stable subcell model for arbitrarily oriented thin wires in the FETD method
Author :
Edelvik, Fredrik ; Ledfelt, Gunnar ; Lötstedt, Per ; Riley, Douglas J.
Author_Institution :
Div. of Sci. Comput., Uppsala Univ., Sweden
Abstract :
A computational subcell model for thin wires is developed for electromagnetic simulations. The Maxwell equations are discretized by a finite element approximation on a tetrahedral grid. The wires are described by a second-order equation for the current. The geometry of the wires can be chosen independent of the volume grid. A symmetric coupling between field and wires yields a stable semi-discrete field-wire system and an unconditionally stable fully discrete field-wire system. The system of equations is in each time step solved by a preconditioned conjugate gradient method. The accuracy of the subcell model is demonstrated for dipole and loop antennas with comparisons with the method of moments and experimental data.
Keywords :
conjugate gradient methods; dipole antennas; electric current; electromagnetic coupling; finite element analysis; loop antennas; numerical stability; time-domain analysis; wire antennas; FETD method; Maxwell equations; computational subcell model; dipole antennas; electric current; electromagnetic simulations; field-wire coupling; finite element approximation; finite-element time-domain method; fully discrete field-wire system; interpolation operator; iterative method; loop antennas; method of moments; preconditioned conjugate gradient method; second-order equation; stability analysis; stable semi-discrete field-wire system; symmetric coupling; tetrahedral grid; thin wires; unconditionally stable subcell model; Computational modeling; Dipole antennas; Electromagnetic modeling; Finite element methods; Geometry; Gradient methods; Maxwell equations; Moment methods; Time domain analysis; Wires;
Journal_Title :
Antennas and Propagation, IEEE Transactions on
DOI :
10.1109/TAP.2003.814750
