Title :
Millimeter-Waves building block design methodology in BiCMOS technology
Author :
Taris, T. ; Deval, Y. ; Severino, R.R. ; Ameziane, C. ; Belot, D. ; Begueret, J.B.
Author_Institution :
IMS Lab., Univ. of Bordeaux, Talence, France
Abstract :
Focusing on circuit routing which is a very critical design step in mm-Waves range, this work proposes a systematic modeling of layout parasitic elements thus fitting measurement and simulation results. Scalable models of extra-device routing elements based on 3D EM software simulations are developed. Two building blocks are so designed and implemented in a 130 nm BiCMOS technology. A two stage cascode LNA which achieves a power gain of 21.14 dB at 61.5 GHz, -21.2 dBm input compression point and a noise figure of 4.3 dB at 60 GHz. The core of the circuit consumes 10.2 mW under 1.2 V. The 64 GHz push-push oscillator operating under 1.8 V, 22 mA, performs a output power of -14 dBm at 68 GHz, the tuning range is about 4 GHz from 64 GHz to 68 GHz.
Keywords :
BiCMOS integrated circuits; integrated circuit layout; integrated circuit modelling; low noise amplifiers; millimetre wave amplifiers; network routing; 3D EM software simulations; BiCMOS technology; cascode LNA; circuit routing; fitting measurement; frequency 60 GHz; frequency 61.5 GHz; frequency 64 GHz to 68 GHz; input compression point; layout parasitic elements; millimeter-waves building block design methodology; size 130 nm; BiCMOS integrated circuits; Circuit simulation; Design methodology; Gain; Millimeter wave circuits; Millimeter wave measurements; Millimeter wave technology; Noise figure; Power system modeling; Routing; 60GHz; BiCMOS9MW; Bipolar/BiCMOS integrated circuit; load pull; low noise amplifier (LNA); millimeter-waves (mm-Waves);
Conference_Titel :
Electronics, Circuits, and Systems, 2009. ICECS 2009. 16th IEEE International Conference on
Conference_Location :
Yasmine Hammamet
Print_ISBN :
978-1-4244-5090-9
Electronic_ISBN :
978-1-4244-5091-6
DOI :
10.1109/ICECS.2009.5410847
