Abstract:
A novel approach to technology integration of system-on-chip RF Front-End Module (FEM) is presented. Device design to achieve best-in-class extended drain power mosfet (E...Show MoreMetadata
Abstract:
A novel approach to technology integration of system-on-chip RF Front-End Module (FEM) is presented. Device design to achieve best-in-class extended drain power mosfet (EDNMOS) with Ron of 1.6Ohm-mm and fT >39GHz is discussed. This is followed by an analysis of a high performance switch device integrated via selective silicon thinning.
Published in: 2016 IEEE International Electron Devices Meeting (IEDM)
Date of Conference: 03-07 December 2016
Date Added to IEEE Xplore: 02 February 2017
ISBN Information:
Electronic ISSN: 2156-017X
GLOBALFOUNDRIES, Singapore
GLOBALFOUNDRIES, Singapore
GLOBALFOUNDRIES, Singapore
GLOBALFOUNDRIES, Singapore
GLOBALFOUNDRIES, Singapore
GLOBALFOUNDRIES, Singapore
GLOBALFOUNDRIES, 60 Woodlands Industrial Park-D, Street-2, Singapore-738406
GLOBALFOUNDRIES, Singapore
GLOBALFOUNDRIES Engineering Private Limited, Bangalore, India
GLOBALFOUNDRIES, Singapore
GLOBALFOUNDRIES, Singapore
School of EEE, Nanyang Technological University, Singapore
Contents GLOBALFOUNDRIES, Singapore
GLOBALFOUNDRIES, Singapore
GLOBALFOUNDRIES, Singapore
GLOBALFOUNDRIES, Singapore
GLOBALFOUNDRIES, Singapore
GLOBALFOUNDRIES, Singapore
GLOBALFOUNDRIES, 60 Woodlands Industrial Park-D, Street-2, Singapore-738406
GLOBALFOUNDRIES, Singapore
GLOBALFOUNDRIES Engineering Private Limited, Bangalore, India
GLOBALFOUNDRIES, Singapore
GLOBALFOUNDRIES, Singapore
School of EEE, Nanyang Technological University, Singapore
