Title :
Low-voltage low-power CMOS-RF transceiver design
Author :
Steyaert, Michiel S J ; De Muer, B. ; Leroux, Paul ; Borremans, Marc ; Mertens, Koen
Author_Institution :
Dept. of Elektrotechniek, Electron., Systems, Automatization & Technol., Katholieke Univ., Leuven, Belgium
fDate :
1/1/2002 12:00:00 AM
Abstract :
Research over the last ten years has resulted in attempts toward single-chip CMOS RF circuits for Bluetooth, global positioning system, digital enhanced cordless telecommunications and cellular applications. An overview of the use of CMOS for low-cost integration of a high-end cellular RF transceiver front-end is presented. Some fundamental pitfalls and limitations of RF CMOS are discussed. To circumvent these obstacles, the choice of transceiver architecture, circuit topology design, and systematic optimization of the different transceiver blocks is necessary. Moreover, optimization of the transceiver as one single block by minimizing the number of power-hungry interface circuits is emphasized. As examples, a fully integrated cellular transceiver front-end, a low-power extremely low noise-figure low-noise amplifier, and a very efficient power amplifier are demonstrated
Keywords :
CMOS integrated circuits; UHF mixers; UHF power amplifiers; cellular radio; phase locked loops; phase noise; superheterodyne receivers; transceivers; white noise; CMOS-RF transceiver design; circuit topology design; efficient power amplifier; fully integrated transceiver front-end; high-end cellular transceiver front-end; image-rejection ratio; low power; low voltage; low-noise amplifier; out-of-band phase noise; phase-locked loop frequency synthesizer; quadrature down-conversion mixers; single-chip RF circuits; systematic optimization; white noise contribution; Band pass filters; CMOS technology; Costs; Impedance; Integrated circuit technology; Low-noise amplifiers; Radio frequency; Space technology; Transceivers; Very large scale integration;
Journal_Title :
Microwave Theory and Techniques, IEEE Transactions on
