Multilayer Design Techniques for Extremely Miniaturized CMOS Microwave and Millimeter-Wave Distributed Passive Circuits

Author

Chirala, Mohan K. ; Nguyen, Cam

Author_Institution

Dept. of Electr. & Comput. Eng., Texas A&M Univ., College Station, TX

Volume

54

Issue

12

fYear

2006

Firstpage

4218

Lastpage

4224

Abstract

Multilayer design techniques are investigated for reducing the size and enhancing the performance of microwave and millimeter-wave distributed circuits in CMOS. Various distributed passive circuits are implemented in a standard 0.25-mum RF/mixed-signal process, including a novel broadside-coupled Lange coupler, a microstrip ring hybrid, and a hairpin resonator incorporating a complementary slow-wave structure. The broadside-coupled Lange coupler exhibits -3.3 to -3.35 dB through, -3.3 to -3.7 dB coupling, more than 12-dB isolation, and 15-dB return loss across 25-35 GHz while occupying only 217 times185 mum of chip area. The multilayer ring hybrid has -3.1 to -3.18 dB through, -5.1 to -5.7 dB coupling, and more than 17-dB isolation and 10-dB return loss from 25-35 GHz while occupying 282 times314 mum. A slow-wave structure based on multilayer complementary design principle is implemented for hairpin resonators. The measured quality factor of the multilayer complementary slow-wave hairpin resonator increases to about 14.5 from 11.3 for a similar sized resonator with a single-layer slow-wave structure, while retaining similar size-reduction properties as the latter

Keywords

CMOS integrated circuits; Q-factor; hybrid integrated circuits; integrated circuit design; microwave integrated circuits; millimetre wave integrated circuits; mixed analogue-digital integrated circuits; passive networks; resonators; slow wave structures; -3.3 to 3.35 dB; 0.25 micron; 25 to 35 GHz; 282 micron; 314 micron; CMOS microwave circuits; RF/mixed-signal process; broadside-coupled Lange coupler; complementary slow-wave structure; distributed passive circuits; hairpin resonator; microstrip ring hybrid; millimeter-wave circuits; multilayer complementary design principle; multilayer design techniques; multilayer ring hybrid; quality factor; Coupling circuits; Microstrip resonators; Microwave circuits; Microwave theory and techniques; Millimeter wave circuits; Millimeter wave technology; Nonhomogeneous media; Passive circuits; Radio frequency; Semiconductor device measurement; CMOS radio-frequency integrated circuits (RFICs); Lange coupler; couplers; hairpin resonator; microwave and millimeter-wave circuits; multilayer circuits; resonators; ring hybrid; slow-wave structures;

fLanguage

English

Journal_Title

Microwave Theory and Techniques, IEEE Transactions on

Publisher

ieee

ISSN

0018-9480

Type

jour

DOI

10.1109/TMTT.2006.885567

Filename

4020436