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DTSTAMP:20220701T074314Z
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DTSTART;TZID=Australia/Adelaide:20220701T143000
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DESCRIPTION:Recently\, with the emergence of bandwidth-intensive applicatio
 ns such as high-resolution streaming media\, 5G\, cloud-based service deli
 very\, and the Internet of Things\, fiber communication network or data tr
 affic has increased exponentially. This rapid increase in traffic in data 
 communications highlights the increased energy demand in traditional infor
 mation and communications technologies. Given the implementation cost and 
 power consumption aspects\, one of the future challenges is to continue de
 veloping core technologies such as transceiver devices and cost-effective 
 optical components. Among the different types of materials used in the mod
 ulator device\, the high-efficient electro-optic (EO) polymer has recently
  received intense research highlights due to the invention of achievable 1
 00 Gbaud and beyond signaling with the extremely reduced power consumption
 .\n\nEO polymers offer important advantages and promise the performance as
 \,\n\nOver 70 GHz EO bandwidth\, theoretically beyond 300 GHz\n\n120 Gbaud
  NRZ electro-optic signaling with sub-one Vpp.\n\nThermal stability testin
 g fully satisfy Telcordia standards or higher temperatures.\n\nPromising u
 seful PAM4 signaling beyond 200 Gbit/s\n\nA highly scalable platform for u
 ltrahigh and ultradense optical communications\n\nPossible thermal resista
 nce up to 110oC and high ambient temperature operation at 100oC\n\nCo-spon
 sored by: Morteza Shahpari\n\nSpeaker(s): Prof. Shiyoshi Yokoyama\, \n\nVi
 rtual: https://events.vtools.ieee.org/m/316509
LOCATION:Virtual: https://events.vtools.ieee.org/m/316509
ORGANIZER:morteza.shahpari@ieee.org
SEQUENCE:4
SUMMARY:Polymer photonics – challenges and approaches for a highly scalab
 le platform in ultradense optical communications
URL;VALUE=URI:https://events.vtools.ieee.org/m/316509
X-ALT-DESC:Description: <br /><p>Recently\, with the emergence of bandwidth
 -intensive applications such as high-resolution streaming media\, 5G\, clo
 ud-based service delivery\, and the Internet of Things\, fiber communicati
 on network or data traffic has increased exponentially. This rapid increas
 e in traffic in data communications highlights the increased energy demand
  in traditional information and communications technologies. Given the imp
 lementation cost and power consumption aspects\, one of the future challen
 ges is to continue developing core technologies such as transceiver device
 s and cost-effective optical components. Among the different types of mate
 rials used in the modulator device\, the high-efficient electro-optic (EO)
  polymer has recently received intense research highlights due to the inve
 ntion of achievable 100 Gbaud and beyond signaling with the extremely redu
 ced power consumption.</p>\n<p><br />EO polymers offer important advantage
 s and promise the performance as\,</p>\n<p>Over 70 GHz EO bandwidth\, theo
 retically beyond 300 GHz</p>\n<p>120 Gbaud NRZ electro-optic signaling wit
 h sub-one Vpp.</p>\n<p>Thermal stability testing fully satisfy Telcordia s
 tandards or higher temperatures.</p>\n<p>Promising useful PAM4 signaling b
 eyond 200 Gbit/s</p>\n<p>A highly scalable platform for ultrahigh and ultr
 adense optical communications</p>\n<p>Possible thermal resistance up to 11
 0oC and high ambient temperature operation at 100oC &nbsp\;</p>
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