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DTSTAMP:20190315T152408Z
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DTSTART;TZID=US/Eastern:20190214T170000
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DESCRIPTION:IEEE MTT/AP/ED Florida West Coast and USF MTT Student Chapter S
 ections Seminar\n\nFrom millibits to Terabits per second and beyond - Over
  70 years of Innovation\n\nSpeaker: Dr. Renuka P. Jindal\, IEEE Fellow and
  EDS Distinguished Lecturer\n\nTime: February 14th\, 2019 (Thursday)\, 5:0
 0pm-6:15pm\n\nLocation: ENC 1002 on the first floor of the Engineering III
  (ENC) building at USF\n\nPresentation Abstract\n\nThe unfolding of the In
 formation Age has led to a plethora of products and services enriching our
  lives and skyrocketing world economy. This advancement in telecommunicati
 ons has been driven by both hardware and software. The circuit complexity\
 , as portrayed by the number of transistors on the silicon chip\, continue
 s to double every 24 months as pointed out by Moore’s law. On the other 
 hand\, the communication bandwidth had doubled every 18 months. This meteo
 ric increase in bandwidth has been made possible by three key developments
  over the last 60 years. The first of these was the demonstration of the p
 oint-contact bipolar transistor in 1947 by Bardeen\, Brattain and Shockley
  which started the solid-state revolution. This was followed by the demons
 tration of the MOS Field-Effect-Transistor by Kahng and Atalla in 1960. Th
 e second key contributor to this bandwidth explosion was the development o
 f Information Theory as enunciated by Claude Shannon in 1948. Once in plac
 e\, this provided a firm theoretical underpinning to understand the trade-
 offs between signal-to-noise ratio\, bandwidth and error-free transmission
  in the presence of noise. The third key development which ignited this fi
 re was the invention of laser by Schawlow and Townes in 1958 with a workin
 g demonstration in 1960. Serious efforts to transform this understanding i
 nto high-performance lightwave systems started by the designing of integra
 ted electronics using MOS technology around 1980. However\, initial attemp
 ts at boosting receiver sensitivity and data-rates was seriously hampered 
 by a lack of understanding of the noise performance of the MOS device. Spe
 aker’s contributions in this area not only led to a deeper understanding
  of the noise behavior of MOS devices but also produced an order of magnit
 ude improvement in their performance. This set the stage for MOS to become
  the technology of choice for lightwave and now low-cost wireless terminal
  applications. The ubiquitous nature of cell phones is a testimony to thes
 e key developments in the early 80’s. In this talk\, starting from smoke
  signals at millibits per second\, we will trace these events from a histo
 rical perspective to see how these key technologies lead to the developmen
 t of modern wireless and optical networks of terabit capacity with petabit
 s looming in sight.\n\nSpeaker(s): Renuka P. Jindal\, \n\nRoom: 1002\, Bld
 g: Engineering III (ENC) building \, 4202 E Fowler Ave\, Tampa\, Florida\,
  United States\, 33620
LOCATION:Room: 1002\, Bldg: Engineering III (ENC) building \, 4202 E Fowler
  Ave\, Tampa\, Florida\, United States\, 33620
ORGANIZER:jingw@usf.edu
SEQUENCE:0
SUMMARY:Invited Talk on "From millibits to Terabits per second and beyond -
  Over 70 years of Innovation" 
URL;VALUE=URI:https://events.vtools.ieee.org/m/195547
X-ALT-DESC:Description: <br /><p><strong>IEEE MTT/AP/ED Florida West Coast 
 and USF MTT Student Chapter Sections Seminar</strong></p>\n<p>&nbsp\;</p>\
 n<p><strong>From millibits to Terabits per second and beyond - Over 70 yea
 rs of Innovation</strong></p>\n<p>&nbsp\;</p>\n<p><strong><u>Speaker</u></
 strong><strong>: Dr. Renuka P. Jindal\, IEEE Fellow and EDS Distinguished 
 Lecturer</strong></p>\n<p><strong><u>Time</u></strong><strong>: February 1
 4<sup>th</sup>\, 2019 (Thursday)\, 5:00pm-6:15pm</strong></p>\n<p><strong>
 <u>Location</u></strong><strong>:</strong> <strong>ENC 1002 on the first f
 loor of the Engineering III (ENC) building at USF</strong></p>\n<p><strong
 >&nbsp\;</strong></p>\n<p><strong>Presentation Abstract</strong></p>\n<p>T
 he unfolding of the Information Age has led to a plethora of products and 
 services enriching our lives and skyrocketing world economy. This advancem
 ent in telecommunications has been driven by both hardware and software. T
 he circuit complexity\, as portrayed by the number of transistors on the s
 ilicon chip\, continues to double every 24 months as pointed out by Moore&
 rsquo\;s law. On the other hand\, the communication bandwidth had doubled 
 every 18 months. This meteoric increase in bandwidth has been made possibl
 e by three key developments over the last 60 years. The first of these was
  the demonstration of the point-contact bipolar transistor in 1947 by Bard
 een\, Brattain and Shockley which started the solid-state revolution. This
  was followed by the demonstration of the MOS Field-Effect-Transistor by K
 ahng and Atalla in 1960. The second key contributor to this bandwidth expl
 osion was the development of Information Theory as enunciated by Claude Sh
 annon in 1948. Once in place\, this provided a firm theoretical underpinni
 ng to understand the trade-offs between signal-to-noise ratio\, bandwidth 
 and error-free transmission in the presence of noise. The third key develo
 pment which ignited this fire was the invention of laser by Schawlow and T
 ownes in 1958 with a working demonstration in 1960. Serious efforts to tra
 nsform this understanding into high-performance lightwave systems started 
 by the designing of integrated electronics using MOS technology around 198
 0. However\, initial attempts at boosting receiver sensitivity and data-ra
 tes was seriously hampered by a lack of understanding of the noise perform
 ance of the MOS device. Speaker&rsquo\;s contributions in this area not on
 ly led to a deeper understanding of the noise behavior of MOS devices but 
 also produced an order of magnitude improvement in their performance. This
  set the stage for MOS to become the technology of choice for lightwave an
 d now low-cost wireless terminal applications. The ubiquitous nature of ce
 ll phones is a testimony to these key developments in the early 80&rsquo\;
 s. In this talk\, starting from smoke signals at millibits per second\, we
  will trace these events from a historical perspective to see how these ke
 y technologies lead to the development of modern wireless and optical netw
 orks of terabit capacity with petabits looming in sight.</p>\n<p><strong>&
 nbsp\;</strong></p>
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