This paper presents a supply modulated X-band 12-W peak power transmitter that maintains an average efficiency greater than 50% for various shapes of amplitude-modulated pulses. The main power amplifier is a two-stage GaN-on-SiC MMIC with a peak efficiency of 65%, while the pulse envelope modulator is a 95% efficient hybrid 3-b power DAC implemented with GaN-on-Si transistor switches. Envelope shaping of a pulsed waveform results in improved spectral confinement of greater than 15 dB for the first sideband compared with constant-envelope pulses, with over 20 points improvement in total efficiency. The combination of supply modulation and digital predistortion is shown to result in high composite (total) efficiency of over 55%, with simultaneous high dynamic range and with flexible digitally programmable pulse shaping.
Florian, C., Cappello, T., Niessen, D., Paganelli, R.P., Schafer, S., Popovic, Z. (2017). Efficient Programmable Pulse Shaping for X-Band GaN MMIC Radar Power Amplifiers. IEEE TRANSACTIONS ON MICROWAVE THEORY AND TECHNIQUES, 65(3), 881-891 [10.1109/TMTT.2016.2631171].
Efficient Programmable Pulse Shaping for X-Band GaN MMIC Radar Power Amplifiers
FLORIAN, CORRADO;CAPPELLO, TOMMASO;NIESSEN, DANIEL;PAGANELLI, RUDI PAOLO;POPOVIC, ZOYA
2017
Abstract
This paper presents a supply modulated X-band 12-W peak power transmitter that maintains an average efficiency greater than 50% for various shapes of amplitude-modulated pulses. The main power amplifier is a two-stage GaN-on-SiC MMIC with a peak efficiency of 65%, while the pulse envelope modulator is a 95% efficient hybrid 3-b power DAC implemented with GaN-on-Si transistor switches. Envelope shaping of a pulsed waveform results in improved spectral confinement of greater than 15 dB for the first sideband compared with constant-envelope pulses, with over 20 points improvement in total efficiency. The combination of supply modulation and digital predistortion is shown to result in high composite (total) efficiency of over 55%, with simultaneous high dynamic range and with flexible digitally programmable pulse shaping.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
