Title :
A Low-Loss Substrate-Independent Approach for 60-GHz Transceiver Front-End Integration Using Micromachining Technologies
Author :
Pan, Bo ; Li, Yuan ; Ponchak, George E. ; Tentzeris, Manos M. ; Papapolymerou, John
Author_Institution :
Realtek Semicond., Irvine, CA
Abstract :
This paper presents a low-loss, substrate-independent approach to integrate transceiver front-ends for 60-GHz wireless applications. Dielectric loss is eliminated by using polymer and bulk silicon micromachining technologies to create a cavity-based duplexer and a horn antenna in the air, above the substrate. A coplanar waveguide input is used for easy integration of the low-noise amplifier and power amplifier of the receiver and transmitter, respectively, with the micromachined passive module. A prototype is designed, fabricated, and characterized, with the transmit band (TX) set between 58.7-59.5 GHz and the receive band (RX) as 60.6-61.4 GHz. The proposed method offers an easy integration of both planar components and 3-D integrated modules on top of the substrate.
Keywords :
coplanar waveguides; elemental semiconductors; horn antennas; low noise amplifiers; micromachining; power amplifiers; silicon; transceivers; 3D integrated modules; cavity-based duplexer; coplanar waveguide; dielectric loss; frequency 58.7 GHz to 61.4 GHz; horn antenna; low-loss substrate-independent approach; low-noise amplifier; micromachined passive module; planar component integration; receiver power amplifier; silicon micromachining technologies; transceiver front-end integration; transmitter power amplifier; wireless applications; 60-GHz; Cavity resonator filter; SU-8; millimeter wave; on-wafer pattern measurement; silicon bulk micromachining; surface micromachining;
Journal_Title :
Microwave Theory and Techniques, IEEE Transactions on
DOI :
10.1109/TMTT.2008.2007358
