Title :
Millimeter-Wave Devices and Circuit Blocks up to 104 GHz in 90 nm CMOS
Author :
Heydari, Babak ; Bohsali, Mounir ; Adabi, Ehsan ; Niknejad, Ali M.
Author_Institution :
Univ. of California, Berkeley
Abstract :
A systematic methodology for layout optimization of active devices for millimeter-wave (mm-wave) application is proposed. A hybrid mm-wave modeling technique was developed to extend the validity of the device compact models up to 100 GHz. These methods resulted in the design of a customized 90 nm device layout which yields an extrapolated of 300 GHz from an intrinsic device . The device is incorporated into a low-power 60 GHz amplifier consuming 10.5 mW, providing 12.2 dB of gain, and an output of 4 dBm. An experimental three-stage 104 GHz tuned amplifier has a measured peak gain of 9.3 dB. Finally, a Colpitts oscillator operating at 104 GHz delivers up to 5 dBm of output power while consuming 6.5 mW.
Keywords :
CMOS integrated circuits; integrated circuit modelling; millimetre wave integrated circuits; CMOS; Colpitts oscillator; amplifier; circuit blocks; frequency 104 GHz; millimeter-wave devices; mm-wave modeling technique; size 90 nm; CMOS technology; Circuits; Gain; Millimeter wave communication; Millimeter wave devices; Millimeter wave radar; Millimeter wave technology; Optimization methods; Oscillators; Semiconductor device modeling; 100 GHz amplifier; 100 GHz oscillator; $f_{max}$ ; CMOS millimeter-wave integrated circuits; high-speed integrated circuits; maximum stable gain; millimeter- wave amplifiers; millimeter-wave device modeling; transmission lines;
Journal_Title :
Solid-State Circuits, IEEE Journal of
DOI :
10.1109/JSSC.2007.908743
