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DTSTART;TZID=Asia/Jerusalem:20240508T170000
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DESCRIPTION:Biography\n\nMark Rodwell holds the Doluca Family Endowed Chair
  in Electrical and Computer Engineering at UCSB and directs the SRC/DARPA 
 Center for Converged TeraHertz Communications and Sensing. His research gr
 oup develops nm and THz transistors\, and high-frequency integrated circui
 ts and systems. Prof. Rodwell received the 2010 IEEE Sarnoff Award\, the 2
 012 Marconi Prize Paper Award\, the 1997 IEEE Microwave Prize\, the 2009 I
 EEE IPRM Conference Award\, and the 1998 European Microwave Conference Mic
 rowave Prize.\n\nAbstract\n\nWe describe the opportunities\, and the resea
 rch challenges\, presented in the development of 100-300GHz wireless commu
 nications and imaging systems. In such links\, short wavelengths permit ma
 ssive spatial multiplexing both for network nodes and point-point links\, 
 permitting aggregate transmission capacities approaching 1Tb/s. 100-300GHz
  radar imaging systems can provide thousands of image pixels and sub-degre
 e angular resolution from small apertures\, supporting foul-weather drivin
 g and aviation. Challenges include the mm-wave IC designs\, the physical d
 esign of the front-end modules\, the complexity of the back-end digital be
 amformer required for spatial multiplexing\, and\, for imaging\, the devel
 opment of system architectures requiring far fewer RF channels than the nu
 mber of image pixels. We will describe transistor development\, IC design\
 , and system design\, and describe our efforts to develop 140GHz massive M
 IMO wireless hubs\, and 210GHz and 280GHz MIMO backhaul links.\n\nVirtual:
  https://events.vtools.ieee.org/m/419492
LOCATION:Virtual: https://events.vtools.ieee.org/m/419492
ORGANIZER:shahar@ee.technion.ac.il
SEQUENCE:3
SUMMARY:100-300 GHz Wireless: transistors\, ICs\, systems - Prof. Mark Rodw
 ell\, University of California\, Santa Barbara
URL;VALUE=URI:https://events.vtools.ieee.org/m/419492
X-ALT-DESC:Description: <br /><h4 class="profile__title bordered"><strong>B
 iography</strong></h4>\n<p>Mark Rodwell holds the Doluca Family Endowed Ch
 air in Electrical and Computer Engineering at UCSB and directs the SRC/DAR
 PA Center for Converged TeraHertz Communications and Sensing. His research
  group develops nm and THz transistors\, and high-frequency integrated cir
 cuits and systems. Prof. Rodwell received the 2010 IEEE Sarnoff Award\, th
 e 2012 Marconi Prize Paper Award\, the 1997 IEEE Microwave Prize\, the 200
 9 IEEE IPRM Conference Award\, and the 1998 European Microwave Conference 
 Microwave Prize.</p>\n<h4><strong>Abstract</strong></h4>\n<p>We describe t
 he opportunities\, and the research challenges\, presented in the developm
 ent of 100-300GHz wireless communications and imaging systems. In such lin
 ks\, short wavelengths permit massive spatial multiplexing both for networ
 k nodes and point-point links\, permitting aggregate transmission capaciti
 es approaching 1Tb/s. 100-300GHz radar imaging systems can provide thousan
 ds of image pixels and sub-degree angular resolution from small apertures\
 , supporting foul-weather driving and aviation. Challenges include the mm-
 wave IC designs\, the physical design of the front-end modules\, the compl
 exity of the back-end digital beamformer required for spatial multiplexing
 \, and\, for imaging\, the development of system architectures requiring f
 ar fewer RF channels than the number of image pixels. We will describe tra
 nsistor development\, IC design\, and system design\, and describe our eff
 orts to develop 140GHz massive MIMO wireless hubs\, and 210GHz and 280GHz 
 MIMO backhaul links.</p>
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