Affiliation:
1. Dept. of Electrical Engineering and Computer Science, University of California at Berkeley, 574 Cory Hall, Berkeley, California 94720 USA, E-mail:ctnguyen@eecs.berkeley.edu
Abstract
Micromechanical (or “μmechanical”) components for communication applications fabricated via IC-compatible MEMS technologies and capable of low-loss filtering, mixing, switching, and frequency generation, are described with the intent to not only miniaturize and lower the parts counts of wireless front-ends via higher levels of integration, but also to eventually raise robustness (against interferers) and lower power consumption when used in alternative architectures that take advantage of the abundant frequency control enabled by RF MEMS devices. Among the devices described are vibrating micromechanical resonators with Q's exceeding 10,000 at GHz frequencies; mechanical circuits comprised of such vibrating resonators; tunable MEMS-based capacitors and inductors with much higher Q than achievable by conventional IC counterparts; and RF MEMS switches with insertion losses and linearity superior to those attainable by present-day semiconductor switches.
Publisher
IMAPS - International Microelectronics Assembly and Packaging Society
Subject
Electrical and Electronic Engineering,Computer Networks and Communications,Electronic, Optical and Magnetic Materials
Cited by
2 articles.
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1. Frequency-scalable fabrication process flow for lithium niobate based Lamb wave resonators;Journal of Micromechanics and Microengineering;2019-12-09
2. Micro-Electromechanical Systems for Underwater Environments;Handbook of Research on Recent Developments in Intelligent Communication Application;2017