Title :
A high-efficiency traveling-wave power amplifier topology using improved power-combining techniques
Author :
Shapiro, Eric S. ; Xu, Jian ; Nagra, Amit S. ; Williams, Freddy, Jr. ; Mishra, U.K. ; York, Robert A.
Author_Institution :
Dept. of Electr. & Comput. Eng., California Univ., Santa Barbara, CA, USA
fDate :
3/1/1998 12:00:00 AM
Abstract :
Traditional distributed amplification techniques have allowed for high gain and bandwidth at the expense of low efficiency. The decreased efficiency is primarily due to the existence of an actively loaded artificial transmission line as the output, resulting in backward wave propagation. Using the same traditional input line distributed techniques to achieve high bandwidth, this research has explored a delay line and corporate combining output topology which improves the travelling-wave amplifier´s (TWAs) efficiency at large signal by elimination of the backward waves. The broad-band output combiner transforms the amplifier load impedance to that of an optimum load for each device, thus realizing a traveling-wave power amplifier. The results for a 1-9-GHz hybrid circuit are presented
Keywords :
coplanar waveguides; delay lines; electric impedance; hybrid integrated circuits; impedance matching; microwave integrated circuits; microwave power amplifiers; power combiners; travelling wave amplifiers; wideband amplifiers; 1 to 9 GHz; SHF; TWA; amplifier load impedance; backward waves elimination; broadband output combiner; corporate combining output topology; delay line; distributed amplification technique; high bandwidth; high-efficiency power amplifier topology; hybrid circuit; input line distributed techniques; optimum load; power-combining techniques; traveling-wave power amplifier; Bandwidth; Circuit topology; Coplanar waveguides; Delay lines; Distributed amplifiers; High power amplifiers; Impedance matching; Power amplifiers; Power combiners; Power transmission lines;
Journal_Title :
Microwave and Guided Wave Letters, IEEE
