Title :
CMOS VCO´s for PLL frequency synthesis in GHz digital mobile radio communications
Author :
Thamsirianunt, Manop ; Kwasniewski, Tadeusz A.
Author_Institution :
Exar Corp., Fremont, CA, USA
fDate :
10/1/1997 12:00:00 AM
Abstract :
CMOS inductorless voltage controlled oscillator (VCO) design is discussed with the emphasis on low-noise, low-power, gigahertz-range circuits suitable for portable wireless equipment. The paper considers three VCO structures-one simple ring oscillator and two differential circuits. The design methodology followed optimization for high-speed and low-power consumption. The proposed linearized MOSFET model allows the accurate prediction of the operating frequency while the phase noise evaluation technique makes it possible to determine, through simulation, the relative phase-noise performance of different oscillator architectures. The measurement results of three VCO´s implemented in 1.2-μm CMOS technology confirm with the simulation predictions. The prototype VCO´s exhibits 926-MHz operation with -83 dBc/Hz phase noise (@ 100 kHz carrier offset) and 5 mW (5 V) power consumption
Keywords :
CMOS analogue integrated circuits; UHF integrated circuits; UHF oscillators; circuit analysis computing; digital radio; frequency synthesizers; mobile radio; phase locked loops; phase noise; relaxation oscillators; voltage-controlled oscillators; 1.2 micron; 5 mW; 926 MHz; CMOS VCO; PLL frequency synthesis; differential circuits; digital mobile radio communications; gigahertz-range circuits; high-speed design; inductorless voltage controlled oscillator; linearized MOSFET model; low-power consumption; operating frequency; oscillator architectures; phase noise evaluation technique; portable wireless equipment; relative phase-noise performance; ring oscillator; simulation predictions; CMOS technology; Circuit synthesis; Design methodology; Frequency synthesizers; Land mobile radio; Phase locked loops; Phase noise; Predictive models; Ring oscillators; Voltage-controlled oscillators;
Journal_Title :
Solid-State Circuits, IEEE Journal of
