Scalable RF MEMS Switch Matrices: Methodology and Design

Author

King Yuk Chan ; Daneshmand, M. ; Mansour, R.R. ; Ramer, R.

Author_Institution

Sch. of Electr. Eng. & Telecommun., Univ. of New South Wales, Sydney, NSW

Volume

57

Issue

6

fYear

2009

fDate

6/1/2009 12:00:00 AM

Firstpage

1612

Lastpage

1621

Abstract

This paper proposes new solutions for implementing wideband large switch matrices. These solutions are based on crossbar and L-shaped topologies. This paper introduces a high-performance wideband switch cell to build up scalable NtimesN switch matrices and gives an account of the design, fabrication, and characteristics of the switch cell and a 3times3 crossbar switch matrix. The chosen design procedure is seen to be appropriate since it produces valid measured results. In addition, this paper presents an RF microelectromechanical systems L-shaped switch matrix, which indicates less variation of characteristics for certain types of connectivity. It also demonstrates that for a 4times4 switch matrix, there is a 50% improvement in insertion loss and phase-shift variation.

Keywords

matrix algebra; microswitches; phase shifters; scaling circuits; L-shaped topology; RF microelectromechanical systems; crossbar topology; high-performance wideband switch cell; insertion loss; phase-shift variation; scalable RF MEMS switch matrices; Design methodology; Fabrication; Micromechanical devices; Radio frequency; Radiofrequency microelectromechanical systems; Switches; Switching circuits; Topology; Transmission line matrix methods; Wideband; Microelectromechanical systems (MEMS); RF MEMS; switch; switch matrix and monolithic microwave integrated circuits;

fLanguage

English

Journal_Title

Microwave Theory and Techniques, IEEE Transactions on

Publisher

ieee

ISSN

0018-9480

Type

jour

DOI

10.1109/TMTT.2009.2020839

Filename

4956996