Title :
High-order numerical solutions of the MFIE for the linear dipole
Author :
Peterson, Andrew F. ; Bibby, Malcolm M.
Author_Institution :
Sch. of Electr. & Comput. Eng., Georgia Inst. of Technol., Atlanta, GA, USA
Abstract :
The magnetic field integral equation (MFIE) was applied to a dipole using three different discretization methods and high-order basis functions. For moderate-order, and higher, basis functions it was found that the different discretization methods produced essentially the same results. Continuity of current and its first derivative was observed at cell boundaries even though continuity of current was not explicitly enforced there. The MFIE provided lower condition numbers than the Hallen equation over the range of dipole radii examined. In close proximity to surface discontinuities, including hidden ones, residual errors could not be significantly reduced by increasing the order of the basis functions, implying the need for better modeling at discontinuities and calling into question the use of faceting to represent curved surfaces.
Keywords :
dipole antennas; electric impedance; linear antennas; magnetic field integral equations; method of moments; Hallen equation; MFIE; MoM; Nystrom method; boundary residual method; dipole radii; discretization method; high-order basis function; input impedance; linear dipole; magnetic field integral equation; method of moment; surface discontinuity; Conductors; Current density; Dipole antennas; Electromagnetic scattering; Feeds; Integral equations; Magnetic fields; Moment methods; Polynomials; Surface impedance; Boundary residual method; MoM; Nystrom methöd; input impedance; integral equations; method of moments;
Journal_Title :
Antennas and Propagation, IEEE Transactions on
DOI :
10.1109/TAP.2004.834407
