An Efficient mm-wave Integrated Circuit Synthesis Method with Accurate Scalable Passive Component Modeling

An Efficient mm-wave Integrated Circuit Synthesis Method with Accurate Scalable Passive Component Modeling

With the operating frequency of radio-frequency (RF) integrated circuits (ICs) ascending gradually to milli-meter-wave (mm-wave) regime, the RF IC design automation methods encounter great challenges due to the complicated distributed effects and parasitic effects. In this work, a new synthesis fram...

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Bibliographic Details
Published in:2018 IEEE Radio Frequency Integrated Circuits Symposium (RFIC) pp. 24 - 27
Main Authors: Zhijian Pan, Wei Zhu, Qiang Yao, Di Li, Zuochang Ye, Yan Wang
Format: Conference Proceeding
Language:English
Published: IEEE 01-06-2018
Subjects:
Computational modeling
Data models
Design automation
Integrated circuit modeling
low-noise amplifier
Mathematical model
mm-wave ICs
Optimization
scalable modeling
Semiconductor device modeling
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Summary:With the operating frequency of radio-frequency (RF) integrated circuits (ICs) ascending gradually to milli-meter-wave (mm-wave) regime, the RF IC design automation methods encounter great challenges due to the complicated distributed effects and parasitic effects. In this work, a new synthesis framework for mm-wave ICs is presented, which is featured by two progressive stages: offline preparation and online synthesis. In the former stage, to cope with the difficulty of mm-wave IC synthesis caused by passive components, a scalable modeling method is proposed, in which geometric parameters are incorporated into rational functions to accurately model the S-parameters up to 120GHz. Benefited from the dedicated offline preparation, during the online synthesis, the circuit performance evaluation and optimization are carried out without the time-consuming EM simulation. High-quality solutions can be obtained by using evolutionary algorithms with enough iterations. We applied the proposed approach to the design of a four-stage differential wideband low-noise amplifier (LNA) covering various mm-wave applications. The synthesized LNA is implemented in 65nm CMOS technology and the measured results show that it achieves the highest bandwidth (34GHz) with other comparable performances to the similar state-of-the-art CMOS broadband LNAs. The synthesis only costs 26min, which is more than 50x time speedUP compared to the existing mm-wave synthesis methods.
ISSN:2375-0995
DOI:10.1109/RFIC.2018.8429004