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DESCRIPTION:Several efforts of the last decade have demonstrated a radio tr
 ansceiver’s ability to simultaneously transmit and receive using the sam
 e frequency band – this is commonly referred to as in-band full duplex c
 ommunication. Numerous performance challenges are presented to the analog\
 , mixed-signal and digital IC designer when attempting to suppress the str
 ong transmitter self-interference (SI) which degrades the receiver’s SND
 R. Specifically\, any SI mitigation circuitry will degrade the RX’s line
 arity\, noise figure\, and reciprocal mixing performance\, moreover these 
 circuits demand high cancellation bandwidth and depth\, in addition to alg
 orithms to adapt and optimize suppression circuits in real-time. Even thou
 gh integrated full duplex transceivers have been the subject of intense re
 search\, the topic of self-interference cancellation is by no means limite
 d to wireless communication systems. In fact\, many other commercial and b
 iomedical applications benefit from the ability to suppress transmitted/em
 itted signals in a system that is attempting simultaneously receive\, sens
 e or record another signal. Examples include neural interfaces\, radar\, w
 ireline communication and medical imaging. This presentation will begin by
  exploring the similarity and differences between the problem of self-inte
 rference/signal cancellation in a very diverse application space. Then\, t
 wo examples of integrated self-interference cancellation systems will be p
 resented\, a neural stimulator/sense front-end and several wireless transc
 eivers which represent the state-of-the-art with respect to linearity\, no
 ise and cancellation depth\, in addition to the ability to adapt mitigatio
 n circuitry in real-time.\n\nSpeaker Bio:\n\nJacques “Chris”tophe Rude
 ll received degrees in electrical engineering from the University of Michi
 gan (BS)\, and UC Berkeley (MS\, PhD). After finish his PhD\, he worked fo
 r several years as an RF IC designer at Berkana Wireless (now Qualcomm)\, 
 and Intel Corporation. In January 2009\, he joined the faculty at the Univ
 ersity of Washington\, Seattle\, where he is now an Associate Professor of
  Electrical and Computer Engineering. He is also a member of the Center fo
 r Neural Technology (CNT) and serves as the co-director of the Center for 
 Design of Analog-Digital Integrated Circuits (CDADIC).\n\nWhile a PhD stud
 ent at UC Berkeley\, Dr. Rudell received the Demetri Angelakos Memorial Ac
 hievement Award\, a citation given to one student per year by the EECS dep
 artment. He has twice been co-recipient of the best paper awards at the IE
 EE International Solid-State Circuits Conference\, the first of which was 
 the 1998 Jack Kilby Award\, followed by the 2001 Lewis Winner Award. He re
 ceived the 2008 ISSCC best evening session award\, and best student paper 
 awards at the 2011 and 2015 RFIC Symposium. Chris is the recipient of the 
 National Science Foundation (NSF) CAREER Award. Dr. Rudell served on the I
 SSCC technical program committee (2003-2010)\, and on the IEEE Radio Frequ
 ency Integrated Circuits (RFIC) Symposium steering committee (2002-2013)\,
  where he was the 2013 General Chair. He was an Associate Editor for the I
 EEE Journal of Solid-State Circuits (2009-2015). At present\, he serves on
  the technical program committees of the IEEE European Solid-State Circuit
 s Conference (ESSCirC) and the IEEE Custom Integrated Circuits Conference 
 (CICC).\n\nSpeaker(s): Prof. Chris Rudell\, \n\nRoom: 3028\, Bldg: Kaiser 
 Building\, Electrical and Computer Engineering\, 2332 Main Mall\, Vancouve
 r\, British Columbia\, Canada\, V6T1Z4\, Virtual: https://events.vtools.ie
 ee.org/m/335185
LOCATION:Room: 3028\, Bldg: Kaiser Building\, Electrical and Computer Engin
 eering\, 2332 Main Mall\, Vancouver\, British Columbia\, Canada\, V6T1Z4\,
  Virtual: https://events.vtools.ieee.org/m/335185
ORGANIZER:sudip@ece.ubc.ca
SEQUENCE:6
SUMMARY:SSCS DL Talk: On-Chip Self-Interference Mitigation for Integrated S
 ystems - Prof. Chris Rudell
URL;VALUE=URI:https://events.vtools.ieee.org/m/335185
X-ALT-DESC:Description: <br /><p><span style="caret-color: #333333\; color:
  #333333\; font-family: 'Helvetica Neue'\, Helvetica\, Verdana\, Arial\, s
 ans-serif\; font-size: 14.666666984558105px\; font-style: normal\; font-va
 riant-caps: normal\; font-weight: normal\; letter-spacing: normal\; orphan
 s: auto\; text-align: justify\; text-indent: 0px\; text-transform: none\; 
 white-space: normal\; widows: auto\; word-spacing: 0px\; -webkit-text-size
 -adjust: auto\; -webkit-text-stroke-width: 0px\; background-color: #ffffff
 \; text-decoration: none\; display: inline !important\; float: none\;">Sev
 eral efforts of the last decade have demonstrated a radio transceiver&rsqu
 o\;s ability to simultaneously transmit and receive using the same frequen
 cy band &ndash\; this is commonly referred to as in-band full duplex commu
 nication. Numerous performance challenges are presented to the analog\, mi
 xed-signal and digital IC designer when attempting to suppress the strong 
 transmitter self-interference (SI) which degrades the receiver&rsquo\;s SN
 DR. Specifically\, any SI mitigation circuitry will degrade the RX&rsquo\;
 s linearity\, noise figure\, and reciprocal mixing performance\, moreover 
 these circuits demand high cancellation bandwidth and depth\, in addition 
 to algorithms to adapt and optimize suppression circuits in real-time. Eve
 n though integrated full duplex transceivers have been the subject of inte
 nse research\, the topic of self-interference cancellation is by no means 
 limited to wireless communication systems. In fact\, many other commercial
  and biomedical applications benefit from the ability to suppress transmit
 ted/emitted signals in a system that is attempting simultaneously receive\
 , sense or record another signal. Examples include neural interfaces\, rad
 ar\, wireline communication and medical imaging. This presentation will be
 gin by exploring the similarity and differences between the problem of sel
 f-interference/signal cancellation in a very diverse application space. Th
 en\, two examples of integrated self-interference cancellation systems wil
 l be presented\, a neural&nbsp\; stimulator/sense front-end and several wi
 reless transceivers which represent the state-of-the-art with respect to l
 inearity\, noise and cancellation depth\, in addition to the ability to ad
 apt mitigation circuitry in real-time.&nbsp\;</span></p>\n<p><span style="
 caret-color: #333333\; color: #333333\; font-family: 'Helvetica Neue'\, He
 lvetica\, Verdana\, Arial\, sans-serif\; font-size: 14.666666984558105px\;
  font-style: normal\; font-variant-caps: normal\; font-weight: normal\; le
 tter-spacing: normal\; orphans: auto\; text-align: justify\; text-indent: 
 0px\; text-transform: none\; white-space: normal\; widows: auto\; word-spa
 cing: 0px\; -webkit-text-size-adjust: auto\; -webkit-text-stroke-width: 0p
 x\; background-color: #ffffff\; text-decoration: none\; display: inline !i
 mportant\; float: none\;">Speaker Bio:</span></p>\n<p style="box-sizing: b
 order-box\; margin: 0px 0px 10px\; caret-color: #333333\; color: #333333\;
  font-family: 'Helvetica Neue'\, Helvetica\, Verdana\, Arial\, sans-serif\
 ; font-size: 14px\; font-style: normal\; font-variant-caps: normal\; font-
 weight: normal\; letter-spacing: normal\; orphans: auto\; text-align: star
 t\; text-indent: 0px\; text-transform: none\; white-space: normal\; widows
 : auto\; word-spacing: 0px\; -webkit-text-size-adjust: auto\; -webkit-text
 -stroke-width: 0px\; text-decoration: none\;">Jacques &ldquo\;Chris&rdquo\
 ;tophe Rudell received degrees in electrical engineering from the Universi
 ty of Michigan (BS)\, and UC Berkeley (MS\, PhD). After finish his PhD\, h
 e worked for several years as an RF IC designer at Berkana Wireless (now Q
 ualcomm)\, and Intel Corporation.&nbsp\; In January 2009\, he joined the f
 aculty at the University of Washington\, Seattle\, where he is now an Asso
 ciate Professor of Electrical and Computer Engineering. He is also a membe
 r of the Center for Neural Technology (CNT) and serves as the co-director 
 of the Center for Design of Analog-Digital Integrated Circuits (CDADIC).</
 p>\n<p style="box-sizing: border-box\; margin: 0px 0px 10px\; caret-color:
  #333333\; color: #333333\; font-family: 'Helvetica Neue'\, Helvetica\, Ve
 rdana\, Arial\, sans-serif\; font-size: 14px\; font-style: normal\; font-v
 ariant-caps: normal\; font-weight: normal\; letter-spacing: normal\; orpha
 ns: auto\; text-align: start\; text-indent: 0px\; text-transform: none\; w
 hite-space: normal\; widows: auto\; word-spacing: 0px\; -webkit-text-size-
 adjust: auto\; -webkit-text-stroke-width: 0px\; text-decoration: none\;"><
 span lang="EN-GB" style="box-sizing: border-box\; text-align: justify\; te
 xt-indent: 0.5in\;">While a PhD student at UC Berkeley\, Dr. Rudell receiv
 ed the Demetri Angelakos Memorial Achievement Award\, a citation given to 
 one student per year by the EECS department. He has twice been co-recipien
 t of the best paper awards at the IEEE International Solid-State Circuits 
 Conference\, the first of which was the 1998 Jack Kilby Award\, followed b
 y the 2001 Lewis Winner Award. He received the 2008 ISSCC best evening ses
 sion award\, and best student paper awards at the 2011 and 2015 RFIC Sympo
 sium. </span><span style="box-sizing: border-box\; text-align: justify\; t
 ext-indent: 0.5in\;">Chris is the recipient of the National Science Founda
 tion (NSF) CAREER Award.</span><span style="box-sizing: border-box\; text-
 align: justify\; text-indent: 0.5in\;"> </span><span style="box-sizing: bo
 rder-box\; text-align: justify\; text-indent: 0.5in\;">Dr. Rudell served o
 n the ISSCC technical program committee (2003-2010)\, and on the </span><s
 pan style="box-sizing: border-box\; text-align: justify\; text-indent: 0.5
 in\;">IEEE Radio Frequency Integrated Circuits</span><span style="box-sizi
 ng: border-box\; text-align: justify\; text-indent: 0.5in\;"> (RFIC) Sympo
 sium steering committee (2002-2013)\, where he was the 2013 General Chair.
  He was an Associate Editor for the </span><span style="box-sizing: border
 -box\; text-align: justify\; text-indent: 0.5in\;">IEEE Journal of Solid-S
 tate Circuits</span><span style="box-sizing: border-box\; text-align: just
 ify\; text-indent: 0.5in\;"> (2009-2015). At present\, he serves on the te
 chnical program committees of the </span><span style="box-sizing: border-b
 ox\; text-align: justify\; text-indent: 0.5in\;">IEEE European Solid-State
  Circuits Conference</span><span style="box-sizing: border-box\; text-alig
 n: justify\; text-indent: 0.5in\;"> (ESSCirC) and the </span><span style="
 box-sizing: border-box\; text-align: justify\; text-indent: 0.5in\;">IEEE 
 Custom Integrated Circuits Conference</span><span style="box-sizing: borde
 r-box\; text-align: justify\; text-indent: 0.5in\;"> (CICC).</span></p>
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