Title :
Decomposition of the moment method impedance matrix into quasi-static and residual components [dipole antennas]
Author :
Simpson, T.L. ; Logan, J.C. ; Rockway, J.W.
Author_Institution :
Dept. of Electr. & Comput. Eng., South Carolina Univ., Colombia, SC, USA
Abstract :
By extending the concept of separating the Green´s function into singular and nonsingular parts to an additive decomposition of the impedance matrix, three matrices, namely, a static elastance matrix which alone determines the static charge; a static inductance matrix which, combined with the elastance matrix determines reactive behavior below resonance; and a residual frequency-dependent matrix are obtained. Using the quasistatic solution and a first-order approximation for the residual matrix, the authors obtain an equivalent circuit valid up to about one-half of the resonant frequency. It is concluded that for electrically small antennas, where radiation bandwidth is limited, this technique offers a novel method to determine circuit limitations. This approach extends the quasistatic theory of distributed circuits to the realm of practical computation
Keywords :
antenna theory; dipole antennas; electric impedance; equivalent circuits; Green´s function; additive decomposition; dipole antennas; electrically small antennas; equivalent circuit; first-order approximation; impedance matrix; moment method; perfectly conducting thin wire dipole; quasistatic solution; reactive behavior; residual frequency-dependent matrix; residual matrix; resonant frequency; static charge; static elastance matrix; static inductance matrix; Bandwidth; Distributed computing; Equivalent circuits; Green´s function methods; Impedance; Inductance; Matrix decomposition; Moment methods; Resonance; Resonant frequency;
Conference_Titel :
Southeastcon '89. Proceedings. Energy and Information Technologies in the Southeast., IEEE
Conference_Location :
Columbia, SC
DOI :
10.1109/SECON.1989.132382
