Don Pavinski
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Publication
Featured researches published by Don Pavinski.
IEEE Journal of Selected Topics in Quantum Electronics | 2011
F. Kish; D. Welch; R. Nagarajan; J. Pleumeekers; Vikrant Lal; Mehrdad Ziari; Alan C. Nilsson; Masaki Kato; Sanjeev Murthy; P. Evans; Scott Corzine; Matthew L. Mitchell; Parmijit Samra; Mark J. Missey; Scott Demars; R. Schneider; M. Reffle; T. Butrie; Jeffrey T. Rahn; M.F. Van Leeuwen; J. W. Stewart; Damien Lambert; Ranjani Muthiah; Huan-Shang Tsai; Jeffrey Bostak; Andrew Dentai; Kuang-Tsan Wu; Han Sun; Don Pavinski; Jiaming Zhang
In this paper, the current state of the art for large-scale InP photonic integrated circuits (PICs) is reviewed with a focus on the devices and technologies that are driving the commercial scaling of highly integrated devices. Specifically, the performance, reliability, and manufacturability of commercial 100-Gb/s dense wavelength-division-multiplexed transmitter and receiver PICs are reviewed as well as next- and future-generation devices (500 Gb/s and beyond). The large-scale PIC enables significant reductions in cost, packaging complexity, size, fiber coupling, and power consumption which have enabled benefits at the component and system level.
optical fiber communication conference | 2011
P. Evans; M. Fisher; Roman Malendevich; Adam James; P. Studenkov; Gilad Goldfarb; T. Vallaitis; Masaki Kato; P. Samra; Scott Corzine; E. Strzelecka; Randal A. Salvatore; F. Sedgwick; Matthias Kuntz; Vikrant Lal; Damien Lambert; Andrew Dentai; Don Pavinski; Jiaming Zhang; Babak Behnia; Jeffrey Bostak; Vincent G. Dominic; Alan C. Nilsson; Brian Taylor; Jeffrey T. Rahn; Steve Sanders; Han Sun; Kuang-Tsan Wu; J. Pleumeekers; Ranjani Muthiah
A 10-wavelength, polarization-multiplexed, monolithically integrated InP transmitter PIC is demonstrated for the first time to operate at 112 Gb/s per wavelength with a coherent receiver PIC.
Optics Express | 2011
P. Evans; M. Fisher; Roman Malendevich; Adam James; Gilad Goldfarb; T. Vallaitis; Masaki Kato; P. Samra; Scott Corzine; E. Strzelecka; P. Studenkov; Randal A. Salvatore; F. Sedgwick; Matthias Kuntz; Lal; Damien Lambert; Andrew Dentai; Don Pavinski; Jiaming Zhang; Cornelius J; Tsai T; Babak Behnia; Jeffrey Bostak; Dominic; Alan C. Nilsson; Brian Taylor; Jeffrey T. Rahn; Steve Sanders; Han Sun; Kuang-Tsan Wu
In this work, a 10-wavelength, polarization-multiplexed, monolithically integrated InP coherent QPSK transmitter PIC is demonstrated to operate at 112 Gb/sec per wavelength and total chip superchannel bandwidth of 1.12 Tb/s. This demonstration suggests that increasing data capacity to multi-Tb/s per chip is possible and likely in the future.
optical fiber communication conference | 2008
Sanjeev Murthy; Masaki Kato; Radhakrishnan Nagarajan; Mark J. Missey; Vince Dominic; Vikrant Lai; Brian Taylor; Jacco Pleumeekers; Jianping Zhang; Peter Evans; Mehrdad Ziari; Ranjani Muthiah; Randal A. Salvatore; Huan-Shang Tsai; Alan Nilson; Don Pavinski; P. Studenkov; Shashank Agashe; Andrew Dentai; Damien Lambert; Jeffrey Bostak; J. Stewart; Charles H. Joyner; Jon Rossi; Richard P. Schneider; M. Reffle; Fred A. Kish; D. O. Welch
We have successfully demonstrated large-scale photonic integrated circuit (LS-PIC) transmitters with monolithically integrated semiconductor optical amplifiers. Data is presented for for 10 channel devices operating at 10 and 40 Gb/sec.
optical fiber communication conference | 2014
Fred A. Kish; M. Reffle; Tim Butrie; Mehrdad Ziari; P. Evans; Scott W. Corzine; Huan-Shang Tsai; Don Pavinski; Jiaming Zhang; Jie Tang; Andrew Dentai; Ranjani Muthiah; Jacco Pleumeekers; Damien Lambert; Mark J. Missey; Vikrant La; M. Fisher; Sanjeev Murthy; Randal A. Salvatore; Scott Demars; Adam James; Jeffrey T. Rahn; Saurabh Kumar; Matthew L. Mitchell; Jianping Zhang; Tiangong Liu; Radhakrishnan Nagarajan; Masaki Kato; D. O. Welch
500-Gb/s transmitter and receiver photonic integrated circuit (PIC) modules are reviewed as well as their scaling to Tb/s and higher data capacities.
Journal of Lightwave Technology | 2017
Vikrant Lal; J. Summers; Naksup Kim; Scott Corzine; Peter Evans; Matthias Lauermann; An Nguyen; Amir Hosseini; Mingzhi Lu; Jeffrey T. Rahn; Mohammad Reza Chitgarha; Jiaming Zhang; John W. Osenbach; T. Vallaitis; Parmijit Samra; Charles Park; Matthias Kuntz; Jie Tang; Corey Tsai; Han Sun; R. Schmogrow; Don Pavinski; Babak Behnia; Pierre Mertz; Tim Butrie; Kuang-Tsan Wu; Matthew L. Mitchell; Mehrdad Ziari; M. Reffle; David F. Welch
We demonstrate a fully integrated multi-channel InP-based coherent transmitter photonic integrated circuits (PICs) with extended C-band tunability, operating at 33 and 44 Gbaud per channel under 16-QAM dual-polarization modulation. PICs are demonstrated integrating up to 14-channels enabling multi-Tb/s total PIC capacities.
Optics Express | 2017
Amir Hosseini; M. Lu; R. Going; P. Samra; S. Amiralizadeh; A. Nguyen; Jeffrey T. Rahn; Vince Dominic; A. Awadalla; Scott Corzine; N. Kim; J. Summers; D. Gold; J. Tang; H-S. Tsai; K. Weidner; P. Abolghasem; Matthias Lauermann; Jiaming Zhang; J. Yan; T. Vallaitis; G. Gilardi; Andrew Dentai; N. Modi; P. Evans; Vikrant Lal; Matthias Kuntz; Don Pavinski; Mehrdad Ziari; J. Osenbach
Fully integrated monolithic, multi-channel InP-based coherent receiver PICs and transceiver modules with extended C-band tunability are described. These PICs operate at 33 and 44 Gbaud per channel under dual polarization (DP) 16-QAM modulation. Fourteen-channel monolithic InP receiver PICs show integration and data rate scaling capability to operate at 44 Gbaud under DP 16-QAM modulation for combined 4.9 Tb/s total capacity. Six channel simultaneous operation of a commercial transceiver module at 33 Gbaud is demonstrated for a variety of modulation formats including DP 16-QAM for >1.2Tbit/s aggregate data capacity.
IEEE Journal of Selected Topics in Quantum Electronics | 2018
Fred A. Kish; Vikrant Lal; Peter Evans; Scott Corzine; Mehrdad Ziari; Tim Butrie; M. Reffle; Huan-Shang Tsai; Andrew Dentai; J. Pleumeekers; Mark J. Missey; M. Fisher; Sanjeev Murthy; Randal A. Salvatore; Parmijit Samra; Scott Demars; Naksup Kim; Adam James; Amir Hosseini; P. Studenkov; Matthias Lauermann; Ryan Going; Mingzhi Lu; Jiaming Zhang; Jie Tang; Jeff Bostak; T. Vallaitis; Matthias Kuntz; Don Pavinski; Andrew Karanicolas
Key advances which enabled the InP photonic integrated circuit (PIC) and the subsequent progression of InP PICs to fully integrated multichannel DWDM system-on-chip (SOC) PICs are described. Furthermore, the current state-of-the-art commercial multichannel SOC PICs are reviewed as well as key trends and technologies for the future of InP-based PICs in optical communications.
Integrated Photonics Research, Silicon and Nanophotonics | 2013
Vikrant Lal; Scott Corzine; P. Evans; M. Fisher; Adam James; P. Studenkov; T. Vallaitis; Masaki Kato; P. Samra; E. Strzelecka; Randal A. Salvatore; F. Sedgwick; Matthias Kuntz; Damien Lambert; Andrew Dentai; Don Pavinski; Jiaming Zhang; Jeffrey Bostak; Vincent G. Dominic; Alan C. Nilsson; Brian Taylor; Jeffrey T. Rahn; S. Sanders; W. Shaw; Han Sun; Corey Tsai; Kuang-Tsan Wu; J. Pleumeekers; Ranjani Muthiah; Mark J. Missey
We report on the development of monolithically integrated multi-wavelength coherent transmitter and receiver PICs employing polarization multiplexing and advanced phase-shift keying modulation to provide an aggregate bandwidth greater than 1Tbps on a single chip.
photonics society summer topical meeting series | 2011
Vikrant Lal; P. Evans; M. Fisher; Roman Malendevich; Adam James; P. Studenkov; Gilad Goldfarb; T. Vallaitis; Masaki Kato; P. Samra; Scott Corzine; E. Strzelecka; Randal A. Salvatore; F. Sedgwick; Matthias Kuntz; Damien Lambert; Andrew Dentai; Don Pavinski; Jiaming Zhang; Babak Behnia; Jeffrey Bostak; Vincent G. Dominic; Alan C. Nilsson; Brian Taylor; Jeffrey T. Rahn; S. Sanders; W. Shaw; Han Sun; Corey Tsai; Kuang-Tsan Wu
In this talk, we report on a pair of monolithically integrated multi-wavelength transmitter and receiver PICs employing polarization multiplexing and quadrature phase-shift keying modulation to provide an aggregate bandwidth greater than 1Tbps on a single chip.
