Title :
A dual-antenna phase-array ultra-wideband CMOS transceiver
Author :
Sever, I. ; Lo, S. ; Ssu-Pin Ma ; Jang, P. ; Zou, A. ; Arnott, C. ; Ghatak, K. ; Schwartz, A. ; Lam Huynh ; Nguyen, T.
Author_Institution :
Tzero Technol., Sunnyvale, CA
Abstract :
Ultra-wideband (UWB) systems use high-bandwidth signals to enable a new generation of ultra-high-data-rate wireless applications. Implementation of a high-bandwidth RF system in the 3-5 GHz band presents challenges that can be solved by circuit and system techniques. This article looks at the motivation and requirements for a WiMedia-compliant UWB system implemented for a target application in wireless video transmission. It explores the circuit-level trade-offs in CMOS radio and some of the system-level methods, such as selection diversity and equal-gain combining, used to increase robustness in multipath and interference environments. The radio (S. Lo, 2006) is part of a two-chip solution that includes a digital baseband chip that implements the WiMedia-compliant PHY and MAC. The measured results of the 0.18 mum CMOS UWB transceiver demonstrate the efficacy of these techniques in the final RF and system performance
Keywords :
CMOS digital integrated circuits; antenna phased arrays; transceivers; ultra wideband antennas; ultra wideband communication; video communication; 3 to 5 GHz; CMOS radio; WiMedia-compliant UWB system; circuit-level trade-offs; digital baseband chip; dual-antenna phase-array; equal-gain combining; high-bandwidth RF system; high-bandwidth signals; interference environment; multipath environment; selection diversity; two-chip solution; ultra-high-data-rate wireless applications; ultra-wideband CMOS transceiver; wireless video transmission; Baseband; Circuits and systems; Diversity reception; Interference; Physical layer; Radio frequency; Robustness; Signal generators; Transceivers; Ultra wideband technology;
Journal_Title :
Communications Magazine, IEEE
DOI :
10.1109/MCOM.2006.1678117
