The input impedance of nonperiodic sources that excite a periodically loaded shielded microstrip line is studied numerically with a rigorous method-of-moments approach based on the array scanning method. Both a delta-gap voltage and an impressed vertical current sheet are considered to be idealized sources exhibiting different symmetry properties. Their input impedances, calculated according to either a power-voltage or a power-current definition, are compared with the Bloch impedance of the dominant mode excited along the structure in a wide frequency range encompassing different propagation regimes of the dominant and of the first higher order mode. Numerical results, validated also through independent full-wave codes, provide physical insight and quantitative information on the mode excitation efficiency and input-impedance features of finite sources in a periodic microstrip environment.
Input Impedance of Nonperiodic Sources Exciting 1-D Periodic Shielded Microstrip Structures / Valerio, Guido; Burghignoli, Paolo; Baccarelli, Paolo; Galli, Alessandro. - In: IEEE TRANSACTIONS ON MICROWAVE THEORY AND TECHNIQUES. - ISSN 0018-9480. - STAMPA. - 58:7 PART 1(2010), pp. 1796-1806. [10.1109/tmtt.2010.2049919]
Input Impedance of Nonperiodic Sources Exciting 1-D Periodic Shielded Microstrip Structures
VALERIO, GUIDO;BURGHIGNOLI, Paolo;BACCARELLI, Paolo;GALLI, Alessandro
2010
Abstract
The input impedance of nonperiodic sources that excite a periodically loaded shielded microstrip line is studied numerically with a rigorous method-of-moments approach based on the array scanning method. Both a delta-gap voltage and an impressed vertical current sheet are considered to be idealized sources exhibiting different symmetry properties. Their input impedances, calculated according to either a power-voltage or a power-current definition, are compared with the Bloch impedance of the dominant mode excited along the structure in a wide frequency range encompassing different propagation regimes of the dominant and of the first higher order mode. Numerical results, validated also through independent full-wave codes, provide physical insight and quantitative information on the mode excitation efficiency and input-impedance features of finite sources in a periodic microstrip environment.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
