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The Resource Datacenter Connectivity Technologies : Principles and Practice

Datacenter Connectivity Technologies : Principles and Practice

Label
Datacenter Connectivity Technologies : Principles and Practice
Title
Datacenter Connectivity Technologies
Title remainder
Principles and Practice
Creator
Contributor
Subject
Language
eng
Member of
Cataloging source
NhCcYBP
http://library.link/vocab/creatorName
Chang, Frank
Dewey number
004
Index
no index present
LC call number
QA76
LC item number
.D383 2018
Literary form
non fiction
Nature of contents
dictionaries
http://library.link/vocab/relatedWorkOrContributorName
ProQuest (Firm)
Series statement
River Publishers Series in Optics and Photonics Ser
http://library.link/vocab/subjectName
Electronic data processing
Label
Datacenter Connectivity Technologies : Principles and Practice
Instantiates
Publication
Note
4.7.3 MPI Experiment with Multiple Connectors
Carrier category
online resource
Carrier category code
  • cr
Carrier MARC source
rdacarrier
Content category
text
Content type code
  • txt
Content type MARC source
rdacontent
Contents
  • 40G Optical Interconnect Technologies
  • 3.6.1.
  • Detuned-Loading Effect
  • Yasuhiro Matsui
  • 3.6.2.
  • S21 High-Pass Filter Effect Due to In-Cavity FM-AM Conversion by the DBR Mirror
  • Yasuhiro Matsui
  • 3.6.3.
  • Photon-Photon Resonance Effect
  • Yasuhiro Matsui
  • 3.6.4.
  • Chongjin Xie
  • Co-Existence of Photon-Photon Resonance and Detuned-Loading Effects
  • Yasuhiro Matsui
  • 3.6.5.
  • 55-GHz Bandwidth Short-Cavity DR Laser and 56 Gbaud PAM4 Generation
  • Yasuhiro Matsui
  • 3.7.
  • Conclusions
  • Yasuhiro Matsui
  • References
  • Yasuhiro Matsui
  • 1.2.2.
  • 4.1.
  • Introduction
  • Winston Way
  • Trevor Chan
  • 4.2.
  • General PAM4 Optical Transceiver and Link Considerations
  • Winston Way
  • Trevor Chan
  • 4.2.1.
  • PAM4 Signal and Optical Link Characteristics
  • 100G Optical Interconnect Technologies
  • Winston Way
  • Trevor Chan
  • 4.2.2.
  • EML Biasing and Nonlinear Equalization
  • Winston Way
  • Trevor Chan
  • 4.2.3.
  • Forward Error Correction (FEC) and Data Rates for PAM4 Links
  • Winston Way
  • Trevor Chan
  • Chongjin Xie
  • 4.2.4.
  • Sampling Rate and Analog Bandwidth
  • Winston Way
  • Trevor Chan
  • 4.2.5.
  • FFE and DFE Equalization
  • Winston Way
  • Trevor Chan
  • 4.3.
  • 28 Gbaud PAM4 Transmission
  • 1.2.3.
  • Winston Way
  • Trevor Chan
  • 4.4.
  • 56 Gbaud PAM4 Transmission over 2 km Experiment
  • Winston Way
  • Trevor Chan
  • 4.5.
  • 40 km PAM4 Transmission
  • Winston Way
  • Trevor Chan
  • 400G and Beyond Optical Interconnect Technologies
  • 4.5.1.
  • Avalanche Photodiode (APD)
  • Winston Way
  • Trevor Chan
  • 4.5.2.
  • Gain Clamped Semiconductor Optical Amplifier (GC-SOA)
  • Winston Way
  • Trevor Chan
  • 4.6.
  • 100 km PAM4 Transmission
  • Chongjin Xie
  • Winston Way
  • Trevor Chan
  • 4.6.1.
  • Experimental Setup
  • Winston Way
  • Trevor Chan
  • 4.6.2.
  • Single Channel Characteristics
  • Trevor Chan
  • Winston Way
  • 1.3.
  • 4.6.3.
  • Effect of Fiber Nonlinearities
  • Winston Way
  • Trevor Chan
  • 4.7.
  • Multipath Interference
  • Winston Way
  • Trevor Chan
  • 4.7.1.
  • Experimental Demonstration of the Upper Bound MPI Scenario
  • Inter-datacenter Interconnects
  • Winston Way
  • Trevor Chan
  • 4.7.2.
  • Time-Domain Mixing Monte Carlo Simulation
  • Winston Way
  • Trevor Chan
  • 4.7.3.
  • MPI Experiment with Multiple Connectors
  • Winston Way
  • Trevor Chan
  • Machine generated contents note:
  • Chongjin Xie
  • 4.8.
  • Summary
  • Winston Way
  • Trevor Chan
  • References
  • Winston Way
  • Trevor Chan
  • 5.1.
  • Introduction
  • John Kamino
  • 1.3.1.
  • Yi Sun
  • 5.2.
  • Fiber Type for Datacenters
  • John Kamino
  • Yi Sun
  • 5.2.1.
  • Multimode Fiber Types for Datacenters
  • John Kamino
  • Yi Sun
  • 5.2.2.
  • Inter-datacenter Interconnects in Metro Networks
  • Single-mode Fiber Types for Datacenters
  • John Kamino
  • Yi Sun
  • 5.2.3.
  • Optical Cabling for Datacenters
  • John Kamino
  • Yi Sun
  • 5.2.4.
  • Multicore (MCF) and Few-Mode Fiber (FMF) for SDM
  • John Kamino
  • Chongjin Xie
  • Yi Sun
  • 5.3.
  • Waveguide Design, Modal Structure, and Time Response of SMF and MMF for Datacenters
  • John Kamino
  • Yi Sun
  • 5.3.1.
  • Fundamentals of Waveguide Design and Mode Structures of SMF and MMF
  • John Kamino
  • Yi Sun
  • 5.3.2.
  • 1.3.2.
  • Fundamentals of the Time Response of Optical Fiber
  • John Kamino
  • Yi Sun
  • 5.4.
  • Multimode Optical Fiber for High-Speed Short-Reach Interconnect
  • John Kamino
  • Yi Sun
  • 5.4.1.
  • Laser-optimized MMF (OM3 and OM4)
  • John Kamino
  • Inter-datacenter Interconnects in WANs
  • Yi Sun
  • 5.4.1.1.
  • What is Laser-optimized MMF?
  • John Kamino
  • Yi Sun
  • 5.4.1.2.
  • Differential Modal Delay (DMD)
  • John Kamino
  • Yi Sun
  • 5.4.1.3.
  • Chongjin Xie
  • Bandwidth of MMF Links
  • John Kamino
  • Yi Sun
  • 5.4.2.
  • Bend-optimized OM3/OM4 and Overfilled Effective Modal Bandwidth
  • John Kamino
  • Yi Sun
  • 5.4.3.
  • Wideband MMF (OM5)
  • John Kamino
  • 1.4.
  • Yi Sun
  • 5.5.
  • High-Speed VCSEL-MMF Short-Reach Optical Interconnect System
  • John Kamino
  • Yi Sun
  • 5.5.1.
  • System Evaluation Methodology
  • John Kamino
  • Yi Sun
  • 5.5.2.
  • Summary
  • High-Speed VCSEL-MMF System Transmission Validation
  • John Kamino
  • Yi Sun
  • 5.5.2.1.
  • 10GBASE-SR transmission over OM3 and OM4 MMF
  • John Kamino
  • Yi Sun
  • 5.5.2.2.
  • 40GBASE-eSR4 and 100G eSR4 extended reach demonstration over OM4 MMF
  • John Kamino
  • Chongjin Xie
  • Yi Sun
  • 5.5.2.3.
  • 40/100 Gbps SWDM over OM5 MMF
  • John Kamino
  • Yi Sun
  • 5.5.2.4.
  • High-Speed PAM4 SWDM transmission over OM5 MMF
  • John Kamino
  • Yi Sun
  • 5.6.
  • 1.1.
  • References
  • Datacom Transmission over Single-Mode Optical Fiber
  • John Kamino
  • Yi Sun
  • 5.7.
  • Conclusions
  • John Kamino
  • Yi Sun
  • References
  • John Kamino
  • Yi Sun
  • Chongjin Xie
  • 6.1.
  • Introduction
  • Frank Chang
  • 6.2.
  • Brief History
  • Frank Chang
  • 6.3.
  • PAM4 IC Implementation Challenges
  • Frank Chang
  • 6.3.1.
  • 2.1.
  • PAM4 Transmit Architectures
  • Frank Chang
  • 6.3.2.
  • PAM4 Receive Architectures
  • Frank Chang
  • 6.4.
  • PAM4 SMF Performance
  • Frank Chang
  • 6.4.1.
  • Experimental Setups
  • Introduction
  • Frank Chang
  • 6.4.2.
  • 1n 40G 10 km Transmission
  • Frank Chang
  • 6.4.3.
  • 2n 100G 10 km and 40 km Transmissions
  • Frank Chang
  • 6.4.4.
  • Technical Options for 200/400G Over SMF
  • Frank Chang
  • Wenbin Jiang
  • 6.5.
  • PAM4 MMF Performance
  • Frank Chang
  • 6.5.1.
  • Experimental Setups
  • Frank Chang
  • 6.5.2.
  • 1n 40G Transmission Over 550m OM4
  • Frank Chang
  • 6.5.3.
  • 2.2.
  • 2n 100/200 Gbps 300 m Transmission
  • Frank Chang
  • 6.5.4.
  • Technical Options for 200/400G Over VCSEL/MMF
  • Frank Chang
  • 6.6.
  • PAM4 for OSNR-limited Systems at 1550 nm
  • Frank Chang
  • 6.6.1.
  • Experimental Setups
  • Technology Fundamentals
  • Frank Chang
  • 6.6.2.
  • OSNR and Dispersion Performance
  • Frank Chang
  • 6.7.
  • PAM4 Compliance Tests
  • Frank Chang
  • 6.7.1.
  • Transmitter Dispersion Eye Closure for PAM4 (TDECQ)
  • Frank Chang
  • Wenbin Jiang
  • 6.7.2.
  • Optical Stressed Receiver Sensitivity
  • Frank Chang
  • 6.8.
  • Single Lambda PAM4
  • Frank Chang
  • 6.9.
  • Summary and Outlook
  • Frank Chang
  • References
  • 2.3.
  • Frank Chang
  • 7.1.
  • Introduction
  • Gordon Ning Liu
  • Tianjian Zuo
  • Liang Zhang
  • 7.2.
  • Brief History of DMT
  • Gordon Ning Liu
  • Tianjian Zuo
  • VCSEL Device Structure
  • Liang Zhang
  • 7.3.
  • How DMT Works
  • Tianjian Zuo
  • Liang Zhang
  • Gordon Ning Liu
  • 7.3.1.
  • FFT/IFFT
  • Liang Zhang
  • Tianjian Zuo
  • Introduction
  • Wenbin Jiang
  • Gordon Ning Liu
  • 7.3.2.
  • Cyclic Prefix
  • Gordon Ning Liu
  • Tianjian Zuo
  • Liang Zhang
  • 7.3.3.
  • Loading Algorithm
  • Tianjian Zuo
  • Liang Zhang
  • 2.4.
  • Gordon Ning Liu
  • 7.3.4.
  • PAPR Suppression
  • Liang Zhang
  • Tianjian Zuo
  • Gordon Ning Liu
  • 7.3.5.
  • Synchronization
  • Gordon Ning Liu
  • Tianjian Zuo
  • VCSEL Material Growth
  • Liang Zhang
  • 7.3.6.
  • Channel Equalization
  • Tianjian Zuo
  • Liang Zhang
  • Gordon Ning Liu
  • 7.4.
  • Advanced DMT Techniques for Metro DCI
  • Liang
  • Wenbin Jiang
  • 2.5.
  • VCSEL Fabrication Process
  • Wenbin Jiang
  • 2.6.
  • Conclusion
  • Wenbin Jiang
  • Chongjin Xie
  • References
  • Wenbin Jiang
  • 3.1.
  • Introduction
  • Yasuhiro Matsui
  • 3.2.
  • Intuitive Picture of the Dynamics of Directly Modulated Lasers
  • Yasuhiro Matsui
  • 3.3.
  • Progress of High-Speed FP and DFB Lasers
  • 1.2.
  • Yasuhiro Matsui
  • 3.3.1.
  • 1.55 om DML
  • Yasuhiro Matsui
  • 3.3.2.
  • 1.3 om DML
  • Yasuhiro Matsui
  • 3.3.3.
  • Short-Wavelength DML
  • Yasuhiro Matsui
  • Intra-datacenter Interconnects
  • 3.4.
  • Reach Extension of DML for PON and Metro Applications
  • Yasuhiro Matsui
  • 3.4.1.
  • Principle of Reach Extension of DML by Tailoring Chirp
  • Yasuhiro Matsui
  • 3.4.2.
  • 10 Git/s Transmission Performance of Adiabatic-and Transient-Chirp Dominant DMLs
  • Yasuhiro Matsui
  • 3.4.3.
  • Chongjin Xie
  • Gain Compression Phenomena
  • Yasuhiro Matsui
  • 3.4.4.
  • Experimental S21 Response and Transmission Performance of a Highly-Damped DBR Laser
  • Yasuhiro Matsui
  • 3.4.5.
  • Thermal Wavelength Drift Stabilization for the Burst-Mode NGPON2 Application
  • Yasuhiro Matsui
  • 3.5.
  • Chirp Managed Laser (CML)
  • 1.2.1.
  • Yasuhiro Matsui
  • 3.5.1.
  • Principles of CML
  • Yasuhiro Matsui
  • 3.5.2.
  • Experimental Demonstrations of CML
  • Yasuhiro Matsui
  • 3.6.
  • New Era of High-Speed DML Toward 100-GHz Bandwidth
  • Yasuhiro Matsui
  • 7.4.2.
  • Generations of SSB-DMT
  • Gordon Ning Liu
  • Tianjian Zuo
  • Liang Zhang
  • 7.4.2.1.
  • Optical filter-based SSB-DMT
  • Gordon Ning Liu
  • Tianjian Zuo
  • Liang Zhang
  • Zhang
  • 7.4.2.2.
  • E/O modulator-based SSB-DMT
  • Gordon Ning Liu
  • Tianjian Zuo
  • Liang Zhang
  • 7.4.3.
  • Generation of EDC-DSB-DMT
  • Gordon Ning Liu
  • Tianjian Zuo
  • Liang Zhang
  • Tianjian Zuo
  • 7.4.4.
  • Generation of Twin-SSB-DMT
  • Gordon Ning Liu
  • Tianjian Zuo
  • Liang Zhang
  • 7.4.5.
  • Generation of SSBI-free Twin-SSB-DMT
  • Gordon Ning Liu
  • Tianjian Zuo
  • Liang Zhang
  • Gordon Ning Liu
  • 7.5.
  • Summary
  • Gordon Ning Liu
  • Tianjian Zuo
  • Liang Zhang
  • References
  • Gordon Ning Liu
  • Tianjian Zuo
  • Liang Zhang
  • 8.1.
  • 7.4.1.
  • Introduction
  • Xin Yin
  • Guy Torfs
  • Johan Bauwelinck
  • 8.2.
  • Three-Level Electrical Duobinary Modulation
  • Xin Yin
  • Guy Torfs
  • Johan Bauwelinck
  • 8.2.1.
  • Principle of CD-induced Power Fading
  • Nyquist Frequency
  • Xin Yin
  • Guy Torfs
  • Johan Bauwelinck
  • 8.2.2.
  • Power Spectral Density
  • Xin Yin
  • Guy Torfs
  • Johan Bauwelinck
  • 8.2.3.
  • Gordon Ning Liu
  • Vertical and Horizontal Eye Openings
  • Xin Yin
  • Guy Torfs
  • Johan Bauwelinck
  • 8.3.
  • 100-Gbps EDB/NRZ Transmitter and Receiver Chipset
  • Xin Yin
  • Guy Torfs
  • Johan Bauwelinck
  • 8.4.
  • Tianjian Zuo
  • EDB/NRZ Transmission with DFB-TWEAM
  • Xin Yin
  • Guy Torfs
  • Johan Bauwelinck
  • 8.5.
  • NRZ-OOK Transmission with GeSi EAM
  • Xin Yin
  • Guy Torfs
  • Johan Bauwelinck --
  • Liang Zhang
  • Xin Yin
  • Datacenters and Photonic Integrated Circuits
  • Demis D. John
  • Grant Brodnik
  • Sarat Gundavarapu
  • Renan L. Moreira
  • Michael Belt
  • Taran Huffman
  • Daniel J. Blumenthal
  • 11.2.
  • InP, Si, and Si3N4 Waveguide Platforms
  • Guy Torfs
  • Demis D. John
  • Grant Brodnik
  • Sarat Gundavarapu
  • Renan L. Moreira
  • Michael Belt
  • Taran Huffman
  • Daniel J. Blumenthal
  • 11.3.
  • Ultra-Low Loss Si3N4/SiO2 Platform
  • Demis D. John
  • Johan Bauwelinck
  • Grant Brodnik
  • Sarat Gundavarapu
  • Renan L. Moreira
  • Michael Belt
  • Taran Huffman
  • Daniel J. Blumenthal
  • 11.4.
  • Integration Building Blocks on the ULL Silicon Nitride Platform
  • Sarat Gundavarapu
  • Renan L. Moreira
  • References
  • Michael Belt
  • Taran Huffman
  • Daniel J. Blumenthal
  • Demis D. John
  • Grant Brodnik
  • 11.4.1.
  • Available PIC Platforms
  • Demis D. John
  • Grant Brodnik
  • Sarat Gundavarapu
  • Xin Yin
  • Renan L. Moreira
  • Michael Belt
  • Taran Huffman
  • Daniel J. Blumenthal
  • 11.5.
  • Ultra-Low Loss PIC Components for Datacom
  • Demis D. John
  • Grant Brodnik
  • Sarat Gundavarapu
  • Renan L. Moreira
  • Guy Torfs
  • Michael Belt
  • Taran Huffman
  • Daniel J. Blumenthal
  • 11.5.1.
  • Low-Loss PICs and Optical Delays
  • Demis D. John
  • Grant Brodnik
  • Sarat Gundavarapu
  • Renan L. Moreira
  • Michael Belt
  • Johan Bauwelinck
  • Taran Huffman
  • Daniel J. Blumenthal
  • 11.5.2.
  • Integrated Dispersion Compensation
  • Demis D. John
  • Grant Brodnik
  • Sarat Gundavarapu
  • Renan L. Moreira
  • Michael Belt
  • Taran Huffman
  • 9.1.
  • Daniel J. Blumenthal
  • 11.5.2.1.
  • Design of an Integrated Dispersion Compensator
  • Demis D. John
  • Grant Brodnik
  • Sarat Gundavarapu
  • Renan L. Moreira
  • Michael Belt
  • Taran Huffman
  • Daniel J. Blumenthal
  • Introduction
  • 11.5.2.2.
  • Demonstration of 40 Gbps NRZ-OOK Dispersion Compensation
  • Demis D. John
  • Grant Brodnik
  • Sarat Gundavarapu
  • Renan L. Moreira
  • Michael Belt
  • Taran Huffman
  • Daniel J. Blumenthal
  • 11.5.2.3.
  • Yuya Yamaguchi
  • Demonstration of 40 Gbps PAM-4 Dispersion Compensation
  • Demis D. John
  • Grant Brodnik
  • Sarat Gundavarapu
  • Renan L. Moreira
  • Michael Belt
  • Taran Huffman
  • Daniel J. Blumenthal
  • 11.5.3.
  • Grating Filters
  • Contents note continued:
  • Hirochika Nakajima
  • Taran Huffman
  • Michael Belt
  • Renan L. Moreira
  • Sarat Gundavarapu
  • Grant Brodnik
  • Demis D. John
  • Daniel J. Blumenthal
  • 11.5.4.
  • Ring Resonator Filters
  • Grant Brodnik
  • 9.2.
  • Sarat Gundavarapu
  • Renan L. Moreira
  • Michael Belt
  • Taran Huffman
  • Daniel J. Blumenthal
  • Demis D. John
  • 11.5.5.
  • High-Extinction Filters
  • Taran Huffman
  • Daniel J. Blumenthal
  • Physical Properties of LN (LiNbO3) Crystal
  • Michael Belt
  • Renan L. Moreira
  • Sarat Gundavarapu
  • Grant Brodnik
  • Demis D. John
  • 11.5.6.
  • C-band Lasers on the Si3N4 Platform
  • Daniel J. Blumenthal
  • Taran Huffman
  • Michael Belt
  • Hirochika Nakajima
  • Renan L. Moreira
  • Sarat Gundavarapu
  • Grant Brodnik
  • Demis D. John
  • 11.6.
  • Silicon-Nitride Waveguide Design
  • Taran Huffman
  • Daniel J. Blumenthal
  • Michael Belt
  • Renan L. Moreira
  • Yuya Yamaguchi
  • Sarat Gundavarapu
  • Grant Brodnik
  • Demis D. John
  • 11.7.
  • Summary
  • Daniel J. Blumenthal
  • Taran Huffman
  • Michael Belt
  • Renan L. Moreira
  • Sarat Gundavarapu
  • 9.3.
  • Grant Brodnik
  • Demis D. John
  • References
  • Taran Huffman
  • Daniel J. Blumenthal
  • Michael Belt
  • Renan L. Moreira
  • Sarat Gundavarapu
  • Grant Brodnik
  • Demis D. John
  • Low-loss Ti-diffused Waveguides on LN Since 1974
  • 12.1.
  • Introduction
  • Steve Yao
  • Wajih Daab
  • Gang He
  • Daniel Gariepy
  • 12.2.
  • Polarization Related Tests
  • Steve Yao
  • Daniel Gariepy
  • Hirochika Nakajima
  • Gang He
  • Wajih Daab
  • 12.2.1.
  • Polarization Mode Dispersion (PMD) Measurement
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Wajih Daab
  • 12.2.2.
  • Polarization Dependent Loss (PDL) Measurement
  • Yuya Yamaguchi
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Wajih Daab
  • 12.2.3.
  • PDR Measurement of Receivers
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Wajih Daab
  • 9.4.
  • 12.2.4.
  • PDL Measurement of Fiber Optic Link
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Wajih Daab
  • 12.2.5.
  • Measuring In-band OSNR by DOP Measurement
  • Steve Yao
  • Daniel Gariepy
  • 8.6.
  • Mach-Zehnder (MZ) Guided-wave Circuit with Y-branches on LN
  • Gang He
  • Wajih Daab
  • 12.2.6.
  • Polarization Emulation for Non-coherent and Coherent Systems
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Wajih Daab
  • 12.3.
  • Optical Signal-to-Noise Ratio Measurement
  • Hirochika Nakajima
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Wajih Daab
  • 12.3.1.
  • Measuring OSNR with an OSA
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Wajih Daab
  • Yuya Yamaguchi
  • 12.4.
  • Characterization of Optical Vector-Modulated Signals
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Wajih Daab
  • 12.4.1.
  • Constellation and IQ Diagrams for Vector-Modulated Signal
  • Steve Yao
  • Daniel Gariepy
  • 9.5.
  • Gang He
  • Wajih Daab
  • 12.4.2.
  • Definitions of EVM, RMS-EVM and TR-EVM
  • Wajih Daab
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • 12.4.3.
  • Relationships between EVMRMS, Q-Factor, OSNR and BER
  • Velocity Matching Between Lightwave and Electric Signal
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Wajih Daab
  • 12.4.4.
  • Characterization of Transmitter Impairments
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Wajih Daab
  • Hirochika Nakajima
  • 12.5.
  • Conclusion
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Wajih Daab
  • References
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Yuya Yamaguchi
  • Wajih Daab
  • 13.1.
  • Introduction
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • 13.1.1.
  • 9.6.
  • Challenges for Short-reach Optical Systems
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • 13.1.1.1.
  • Cost
  • Kangping Zhong
  • Stabilization of LN-MZM Operation
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • 13.1.1.2.
  • Form factor
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Hirochika Nakajima
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • 13.1.1.3.
  • Latency
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • SM LW-VCSEL EDB Links
  • Yuya Yamaguchi
  • Jiahao Huo
  • 13.1.2.
  • Different Types of Short-reach Systems
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • 13.1.2.1.
  • 9.7.
  • Server-to-server or Intra-data-center links
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • 13.1.2.2.
  • Inter data-center links
  • Alan Pak Tao Lau
  • External Modulation by LN-MZM Accompanied with EDFA Repeating
  • Chao Lu
  • Jiahao Huo
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • 13.1.2.3.
  • Extended Reach Inter-data-center, Access, and Metro Links
  • Kangping Zhong
  • Xian Zhou
  • Jiahao Huo
  • Hirochika Nakajima
  • Alan Pak Tao Lau
  • Chao Lu
  • Li Zeng
  • 13.2.
  • Modulation Formats for Short-reach Systems
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Yuya Yamaguchi
  • Jiahao Huo
  • 13.2.1.
  • Pulse Amplitude Modulation (PAM)
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • 9.8.
  • Vector Modulation with LN-MZM for Digital Coherent Optical Communications
  • Hirochika Nakajima
  • Yuya Yamaguchi
  • 9.9.
  • Xin Yin
  • Current Status of LN-MZM and Future Potential
  • Hirochika Nakajima
  • Yuya Yamaguchi
  • 9.10.
  • Summary
  • Hirochika Nakajima
  • Yuya Yamaguchi
  • References
  • Hirochika Nakajima
  • Yuya Yamaguchi
  • Guy Torfs
  • 10.1.
  • Introduction
  • Radhakrishnan Nagarajan
  • Mark Filer
  • 10.2.
  • Datacenter Interconnect-Edge
  • Radhakrishnan Nagarajan
  • Mark Filer
  • 10.3.
  • Switch Pluggable 100Gbit/s DWDM Module
  • Johan Bauwelinck
  • Radhakrishnan Nagarajan
  • Mark Filer
  • 10.4.
  • PAM4 DSP ASIC
  • Radhakrishnan Nagarajan
  • Mark Filer
  • 10.5.
  • Silicon Photonics
  • Radhakrishnan Nagarajan
  • Mark Filer
  • 8.7.
  • 10.6.
  • Module and Transmission Performance
  • Radhakrishnan Nagarajan
  • Mark Filer
  • 10.7.
  • Live Datacenter Deployments
  • Radhakrishnan Nagarajan
  • Mark Filer
  • 10.8.
  • Evolution to Switch Pluggable 400-Gbit/s DWDM Module
  • Conclusion
  • Radhakrishnan Nagarajan
  • Mark Filer
  • 10.9.
  • Conclusion
  • Radhakrishnan Nagarajan
  • Mark Filer
  • References
  • Radhakrishnan Nagarajan
  • Mark Filer
  • 11.1.
  • Chao Lu
  • Jiahao Huo
  • 13.2.3.
  • Discrete Multi-tone (DMT) Modulation
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • /
  • 13.2.4.
  • Performance Comparison of Modulation Formats
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • 13.2.5.
  • Complexity Comparison of Modulation Formats
  • Jiahao Huo
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • 13.2.6.
  • Recent Experiment on High-Speed Short-reach Transmission Systems
  • Kangping Zhong
  • Xian Zhou
  • 13.2.2.
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • 13.3.
  • Digital Signal Processing for Short-reach Systems
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Carry-less Amplitude and Phase (CAP) Modulation
  • Chao Lu
  • Jiahao Huo
  • 13.3.1.
  • Feed-forward Equalizer (FFE)
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • Kangping Zhong
  • 13.3.2.
  • Decision Feedback Equalizer (DFE)
  • Xian Zhou
  • Jiahao Huo
  • Kangping Zhong
  • Chao Lu
  • Li Zeng
  • Alan Pak Tao Lau
  • 13.3.3.
  • Direct Detection Faster-than Nyquist (DD-FTN)
  • Xian Zhou
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • 13.3.4.
  • Volterra-series Based Nonlinear Equalizer (VNLE)
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo --
  • Alan Pak Tao Lau
  • Jiahao Huo
  • Intensity-only POL-MUX-DM Coherent System
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.2.2.
  • Complex DM Model
  • Di Che
  • An Li
  • 13.4.1.
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.2.3.
  • 100-Gb/s CDM Transmission Over 1600-km SMF
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • Stokes-vector Direct Detection (SV-DD) Receiver
  • 14.3.
  • Polarization Modulation in Stokes Space
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.3.1.
  • Stokes-space Modulation
  • Di Che
  • Kangping Zhong
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.3.2.
  • Universal MIMO Equalization in Stokes Space
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xian Zhou
  • Xi Chen
  • 14.3.3.
  • Self-coherent SSM
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.3.4.
  • Multi-Dimensional IM in Stokes Space
  • Li Zeng
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.4.
  • Noncoherent Polarization Multiplexing
  • Di Che
  • An Li
  • William Shieh
  • Alan Pak Tao Lau
  • Qian Hu
  • Xi Chen
  • 14.4.1.
  • Degree of Coherence in POL-MUX Transmitter
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.4.2.
  • Chao Lu
  • Noncoherent POL-MUX Schemes
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.5.
  • Summary
  • Di Che
  • An Li
  • Jiahao Huo
  • William Shieh
  • Qian Hu
  • Xi Chen
  • References
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 15.1.
  • 13.4.2.
  • Introduction
  • Glenn A. Wellbrock
  • Tiejun J. Xia
  • 15.2.
  • Why Optical Coherent Transmission?
  • Glenn A. Wellbrock
  • Tiejun J. Xia
  • 15.3.
  • Optical Transport Network with Coherent Transmission
  • Glenn A. Wellbrock
  • Contents note continued:
  • 2-Dimensional (2D) PDM-DD System Based on SV-DD Receiver
  • Tiejun J. Xia
  • 15.4.
  • What's Next for Optical Transport Network?
  • Glenn A. Wellbrock
  • Tiejun J. Xia
  • 15.5.
  • Coherent Transport Technology Development by Network Operators
  • Glenn A. Wellbrock
  • Tiejun J. Xia
  • 15.6.
  • Kangping Zhong
  • Datacenter Connections and Coherent Transport Networks
  • Glenn A. Wellbrock
  • Tiejun J. Xia
  • 15.7.
  • Conclusions
  • Glenn A. Wellbrock
  • Tiejun J. Xia
  • References
  • Glenn A. Wellbrock
  • Tiejun J. Xia
  • Xian Zhou
  • 16.1.
  • Introduction
  • Jung Han Choi
  • 16.2.
  • IC Design for Low Power Consumption
  • Jung Han Choi
  • 16.2.1.
  • Design Requirements
  • Jung Han Choi
  • 16.2.2.
  • Li Zeng
  • IC Architectures for Low Power Consumption
  • Jung Han Choi
  • 16.2.3.
  • Driver-IC Design
  • Jung Han Choi
  • 16.2.3.1.
  • Unit-cell design
  • Jung Han Choi
  • 16.2.3.2.
  • Circuit Simulations
  • Alan Pak Tao Lau
  • Jung Han Choi
  • 16.3.
  • Co-design and Electro-optical Simulation
  • Jung Han Choi
  • 16.3.1.
  • Low-power CoC Design
  • Jung Han Choi
  • 16.3.2.
  • Co-simulation of Driver-IC with EML
  • Jung Han Choi
  • Chao Lu
  • 16.3.2.1.
  • Electrical Time-domain Simulations
  • Jung Han Choi
  • 16.3.2.2.
  • Electro-optical Time-domain Simulations
  • Jung Han Choi
  • 16.4.
  • Measurements
  • Jung Han Choi
  • 16.4.1.
  • Jiahao Huo
  • EO Measurements
  • Jung Han Choi
  • 16.4.2.
  • Transmission Experiments
  • Jung Han Choi
  • 16.5.
  • Conclusion and Perspective
  • Jung Han Choi
  • References
  • Jung Han Choi
  • 13.4.3.
  • 3-Dimensional (3D) PDM-DD System Based on SV-DD Receiver
  • Kangping Zhong
  • 13.4.
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • 13.5.
  • Conclusion
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Polarization Division Multiplexed Transmission for Short-reach Systems
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • References
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • Kangping Zhong
  • 14.1.
  • Optical Detection with Polarization Diversity
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.1.1.
  • Need of Polarization-Diversity Detection
  • Di Che
  • Xian Zhou
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.1.2.
  • Automatic Polarization Control
  • An Li
  • Xi Chen
  • Di Che
  • William Shieh
  • Li Zeng
  • Qian Hu
  • 14.1.3.
  • Polarization-Diversity Detection in Jones Space
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.1.4.
  • Barrier of Self-Polarization Diversity
  • Alan Pak Tao Lau
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.1.5.
  • Polarization-Diversity Detection in Stokes Space
  • Di Che
  • An Li
  • William Shieh
  • Chao Lu
  • Qian Hu
  • Xi Chen
  • 14.2.
  • Direct Modulation with Coherent Receiver
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.2.1.
Control code
MSTDDA5493980
Dimensions
unknown
Extent
1 online resource ( 760 pages.):
Form of item
online
Isbn
9788793609211
Media category
computer
Media MARC source
rdamedia
Media type code
  • c
Reproduction note
Electronic reproduction.
Specific material designation
remote
Label
Datacenter Connectivity Technologies : Principles and Practice
Publication
Note
4.7.3 MPI Experiment with Multiple Connectors
Carrier category
online resource
Carrier category code
  • cr
Carrier MARC source
rdacarrier
Content category
text
Content type code
  • txt
Content type MARC source
rdacontent
Contents
  • 40G Optical Interconnect Technologies
  • 3.6.1.
  • Detuned-Loading Effect
  • Yasuhiro Matsui
  • 3.6.2.
  • S21 High-Pass Filter Effect Due to In-Cavity FM-AM Conversion by the DBR Mirror
  • Yasuhiro Matsui
  • 3.6.3.
  • Photon-Photon Resonance Effect
  • Yasuhiro Matsui
  • 3.6.4.
  • Chongjin Xie
  • Co-Existence of Photon-Photon Resonance and Detuned-Loading Effects
  • Yasuhiro Matsui
  • 3.6.5.
  • 55-GHz Bandwidth Short-Cavity DR Laser and 56 Gbaud PAM4 Generation
  • Yasuhiro Matsui
  • 3.7.
  • Conclusions
  • Yasuhiro Matsui
  • References
  • Yasuhiro Matsui
  • 1.2.2.
  • 4.1.
  • Introduction
  • Winston Way
  • Trevor Chan
  • 4.2.
  • General PAM4 Optical Transceiver and Link Considerations
  • Winston Way
  • Trevor Chan
  • 4.2.1.
  • PAM4 Signal and Optical Link Characteristics
  • 100G Optical Interconnect Technologies
  • Winston Way
  • Trevor Chan
  • 4.2.2.
  • EML Biasing and Nonlinear Equalization
  • Winston Way
  • Trevor Chan
  • 4.2.3.
  • Forward Error Correction (FEC) and Data Rates for PAM4 Links
  • Winston Way
  • Trevor Chan
  • Chongjin Xie
  • 4.2.4.
  • Sampling Rate and Analog Bandwidth
  • Winston Way
  • Trevor Chan
  • 4.2.5.
  • FFE and DFE Equalization
  • Winston Way
  • Trevor Chan
  • 4.3.
  • 28 Gbaud PAM4 Transmission
  • 1.2.3.
  • Winston Way
  • Trevor Chan
  • 4.4.
  • 56 Gbaud PAM4 Transmission over 2 km Experiment
  • Winston Way
  • Trevor Chan
  • 4.5.
  • 40 km PAM4 Transmission
  • Winston Way
  • Trevor Chan
  • 400G and Beyond Optical Interconnect Technologies
  • 4.5.1.
  • Avalanche Photodiode (APD)
  • Winston Way
  • Trevor Chan
  • 4.5.2.
  • Gain Clamped Semiconductor Optical Amplifier (GC-SOA)
  • Winston Way
  • Trevor Chan
  • 4.6.
  • 100 km PAM4 Transmission
  • Chongjin Xie
  • Winston Way
  • Trevor Chan
  • 4.6.1.
  • Experimental Setup
  • Winston Way
  • Trevor Chan
  • 4.6.2.
  • Single Channel Characteristics
  • Trevor Chan
  • Winston Way
  • 1.3.
  • 4.6.3.
  • Effect of Fiber Nonlinearities
  • Winston Way
  • Trevor Chan
  • 4.7.
  • Multipath Interference
  • Winston Way
  • Trevor Chan
  • 4.7.1.
  • Experimental Demonstration of the Upper Bound MPI Scenario
  • Inter-datacenter Interconnects
  • Winston Way
  • Trevor Chan
  • 4.7.2.
  • Time-Domain Mixing Monte Carlo Simulation
  • Winston Way
  • Trevor Chan
  • 4.7.3.
  • MPI Experiment with Multiple Connectors
  • Winston Way
  • Trevor Chan
  • Machine generated contents note:
  • Chongjin Xie
  • 4.8.
  • Summary
  • Winston Way
  • Trevor Chan
  • References
  • Winston Way
  • Trevor Chan
  • 5.1.
  • Introduction
  • John Kamino
  • 1.3.1.
  • Yi Sun
  • 5.2.
  • Fiber Type for Datacenters
  • John Kamino
  • Yi Sun
  • 5.2.1.
  • Multimode Fiber Types for Datacenters
  • John Kamino
  • Yi Sun
  • 5.2.2.
  • Inter-datacenter Interconnects in Metro Networks
  • Single-mode Fiber Types for Datacenters
  • John Kamino
  • Yi Sun
  • 5.2.3.
  • Optical Cabling for Datacenters
  • John Kamino
  • Yi Sun
  • 5.2.4.
  • Multicore (MCF) and Few-Mode Fiber (FMF) for SDM
  • John Kamino
  • Chongjin Xie
  • Yi Sun
  • 5.3.
  • Waveguide Design, Modal Structure, and Time Response of SMF and MMF for Datacenters
  • John Kamino
  • Yi Sun
  • 5.3.1.
  • Fundamentals of Waveguide Design and Mode Structures of SMF and MMF
  • John Kamino
  • Yi Sun
  • 5.3.2.
  • 1.3.2.
  • Fundamentals of the Time Response of Optical Fiber
  • John Kamino
  • Yi Sun
  • 5.4.
  • Multimode Optical Fiber for High-Speed Short-Reach Interconnect
  • John Kamino
  • Yi Sun
  • 5.4.1.
  • Laser-optimized MMF (OM3 and OM4)
  • John Kamino
  • Inter-datacenter Interconnects in WANs
  • Yi Sun
  • 5.4.1.1.
  • What is Laser-optimized MMF?
  • John Kamino
  • Yi Sun
  • 5.4.1.2.
  • Differential Modal Delay (DMD)
  • John Kamino
  • Yi Sun
  • 5.4.1.3.
  • Chongjin Xie
  • Bandwidth of MMF Links
  • John Kamino
  • Yi Sun
  • 5.4.2.
  • Bend-optimized OM3/OM4 and Overfilled Effective Modal Bandwidth
  • John Kamino
  • Yi Sun
  • 5.4.3.
  • Wideband MMF (OM5)
  • John Kamino
  • 1.4.
  • Yi Sun
  • 5.5.
  • High-Speed VCSEL-MMF Short-Reach Optical Interconnect System
  • John Kamino
  • Yi Sun
  • 5.5.1.
  • System Evaluation Methodology
  • John Kamino
  • Yi Sun
  • 5.5.2.
  • Summary
  • High-Speed VCSEL-MMF System Transmission Validation
  • John Kamino
  • Yi Sun
  • 5.5.2.1.
  • 10GBASE-SR transmission over OM3 and OM4 MMF
  • John Kamino
  • Yi Sun
  • 5.5.2.2.
  • 40GBASE-eSR4 and 100G eSR4 extended reach demonstration over OM4 MMF
  • John Kamino
  • Chongjin Xie
  • Yi Sun
  • 5.5.2.3.
  • 40/100 Gbps SWDM over OM5 MMF
  • John Kamino
  • Yi Sun
  • 5.5.2.4.
  • High-Speed PAM4 SWDM transmission over OM5 MMF
  • John Kamino
  • Yi Sun
  • 5.6.
  • 1.1.
  • References
  • Datacom Transmission over Single-Mode Optical Fiber
  • John Kamino
  • Yi Sun
  • 5.7.
  • Conclusions
  • John Kamino
  • Yi Sun
  • References
  • John Kamino
  • Yi Sun
  • Chongjin Xie
  • 6.1.
  • Introduction
  • Frank Chang
  • 6.2.
  • Brief History
  • Frank Chang
  • 6.3.
  • PAM4 IC Implementation Challenges
  • Frank Chang
  • 6.3.1.
  • 2.1.
  • PAM4 Transmit Architectures
  • Frank Chang
  • 6.3.2.
  • PAM4 Receive Architectures
  • Frank Chang
  • 6.4.
  • PAM4 SMF Performance
  • Frank Chang
  • 6.4.1.
  • Experimental Setups
  • Introduction
  • Frank Chang
  • 6.4.2.
  • 1n 40G 10 km Transmission
  • Frank Chang
  • 6.4.3.
  • 2n 100G 10 km and 40 km Transmissions
  • Frank Chang
  • 6.4.4.
  • Technical Options for 200/400G Over SMF
  • Frank Chang
  • Wenbin Jiang
  • 6.5.
  • PAM4 MMF Performance
  • Frank Chang
  • 6.5.1.
  • Experimental Setups
  • Frank Chang
  • 6.5.2.
  • 1n 40G Transmission Over 550m OM4
  • Frank Chang
  • 6.5.3.
  • 2.2.
  • 2n 100/200 Gbps 300 m Transmission
  • Frank Chang
  • 6.5.4.
  • Technical Options for 200/400G Over VCSEL/MMF
  • Frank Chang
  • 6.6.
  • PAM4 for OSNR-limited Systems at 1550 nm
  • Frank Chang
  • 6.6.1.
  • Experimental Setups
  • Technology Fundamentals
  • Frank Chang
  • 6.6.2.
  • OSNR and Dispersion Performance
  • Frank Chang
  • 6.7.
  • PAM4 Compliance Tests
  • Frank Chang
  • 6.7.1.
  • Transmitter Dispersion Eye Closure for PAM4 (TDECQ)
  • Frank Chang
  • Wenbin Jiang
  • 6.7.2.
  • Optical Stressed Receiver Sensitivity
  • Frank Chang
  • 6.8.
  • Single Lambda PAM4
  • Frank Chang
  • 6.9.
  • Summary and Outlook
  • Frank Chang
  • References
  • 2.3.
  • Frank Chang
  • 7.1.
  • Introduction
  • Gordon Ning Liu
  • Tianjian Zuo
  • Liang Zhang
  • 7.2.
  • Brief History of DMT
  • Gordon Ning Liu
  • Tianjian Zuo
  • VCSEL Device Structure
  • Liang Zhang
  • 7.3.
  • How DMT Works
  • Tianjian Zuo
  • Liang Zhang
  • Gordon Ning Liu
  • 7.3.1.
  • FFT/IFFT
  • Liang Zhang
  • Tianjian Zuo
  • Introduction
  • Wenbin Jiang
  • Gordon Ning Liu
  • 7.3.2.
  • Cyclic Prefix
  • Gordon Ning Liu
  • Tianjian Zuo
  • Liang Zhang
  • 7.3.3.
  • Loading Algorithm
  • Tianjian Zuo
  • Liang Zhang
  • 2.4.
  • Gordon Ning Liu
  • 7.3.4.
  • PAPR Suppression
  • Liang Zhang
  • Tianjian Zuo
  • Gordon Ning Liu
  • 7.3.5.
  • Synchronization
  • Gordon Ning Liu
  • Tianjian Zuo
  • VCSEL Material Growth
  • Liang Zhang
  • 7.3.6.
  • Channel Equalization
  • Tianjian Zuo
  • Liang Zhang
  • Gordon Ning Liu
  • 7.4.
  • Advanced DMT Techniques for Metro DCI
  • Liang
  • Wenbin Jiang
  • 2.5.
  • VCSEL Fabrication Process
  • Wenbin Jiang
  • 2.6.
  • Conclusion
  • Wenbin Jiang
  • Chongjin Xie
  • References
  • Wenbin Jiang
  • 3.1.
  • Introduction
  • Yasuhiro Matsui
  • 3.2.
  • Intuitive Picture of the Dynamics of Directly Modulated Lasers
  • Yasuhiro Matsui
  • 3.3.
  • Progress of High-Speed FP and DFB Lasers
  • 1.2.
  • Yasuhiro Matsui
  • 3.3.1.
  • 1.55 om DML
  • Yasuhiro Matsui
  • 3.3.2.
  • 1.3 om DML
  • Yasuhiro Matsui
  • 3.3.3.
  • Short-Wavelength DML
  • Yasuhiro Matsui
  • Intra-datacenter Interconnects
  • 3.4.
  • Reach Extension of DML for PON and Metro Applications
  • Yasuhiro Matsui
  • 3.4.1.
  • Principle of Reach Extension of DML by Tailoring Chirp
  • Yasuhiro Matsui
  • 3.4.2.
  • 10 Git/s Transmission Performance of Adiabatic-and Transient-Chirp Dominant DMLs
  • Yasuhiro Matsui
  • 3.4.3.
  • Chongjin Xie
  • Gain Compression Phenomena
  • Yasuhiro Matsui
  • 3.4.4.
  • Experimental S21 Response and Transmission Performance of a Highly-Damped DBR Laser
  • Yasuhiro Matsui
  • 3.4.5.
  • Thermal Wavelength Drift Stabilization for the Burst-Mode NGPON2 Application
  • Yasuhiro Matsui
  • 3.5.
  • Chirp Managed Laser (CML)
  • 1.2.1.
  • Yasuhiro Matsui
  • 3.5.1.
  • Principles of CML
  • Yasuhiro Matsui
  • 3.5.2.
  • Experimental Demonstrations of CML
  • Yasuhiro Matsui
  • 3.6.
  • New Era of High-Speed DML Toward 100-GHz Bandwidth
  • Yasuhiro Matsui
  • 7.4.2.
  • Generations of SSB-DMT
  • Gordon Ning Liu
  • Tianjian Zuo
  • Liang Zhang
  • 7.4.2.1.
  • Optical filter-based SSB-DMT
  • Gordon Ning Liu
  • Tianjian Zuo
  • Liang Zhang
  • Zhang
  • 7.4.2.2.
  • E/O modulator-based SSB-DMT
  • Gordon Ning Liu
  • Tianjian Zuo
  • Liang Zhang
  • 7.4.3.
  • Generation of EDC-DSB-DMT
  • Gordon Ning Liu
  • Tianjian Zuo
  • Liang Zhang
  • Tianjian Zuo
  • 7.4.4.
  • Generation of Twin-SSB-DMT
  • Gordon Ning Liu
  • Tianjian Zuo
  • Liang Zhang
  • 7.4.5.
  • Generation of SSBI-free Twin-SSB-DMT
  • Gordon Ning Liu
  • Tianjian Zuo
  • Liang Zhang
  • Gordon Ning Liu
  • 7.5.
  • Summary
  • Gordon Ning Liu
  • Tianjian Zuo
  • Liang Zhang
  • References
  • Gordon Ning Liu
  • Tianjian Zuo
  • Liang Zhang
  • 8.1.
  • 7.4.1.
  • Introduction
  • Xin Yin
  • Guy Torfs
  • Johan Bauwelinck
  • 8.2.
  • Three-Level Electrical Duobinary Modulation
  • Xin Yin
  • Guy Torfs
  • Johan Bauwelinck
  • 8.2.1.
  • Principle of CD-induced Power Fading
  • Nyquist Frequency
  • Xin Yin
  • Guy Torfs
  • Johan Bauwelinck
  • 8.2.2.
  • Power Spectral Density
  • Xin Yin
  • Guy Torfs
  • Johan Bauwelinck
  • 8.2.3.
  • Gordon Ning Liu
  • Vertical and Horizontal Eye Openings
  • Xin Yin
  • Guy Torfs
  • Johan Bauwelinck
  • 8.3.
  • 100-Gbps EDB/NRZ Transmitter and Receiver Chipset
  • Xin Yin
  • Guy Torfs
  • Johan Bauwelinck
  • 8.4.
  • Tianjian Zuo
  • EDB/NRZ Transmission with DFB-TWEAM
  • Xin Yin
  • Guy Torfs
  • Johan Bauwelinck
  • 8.5.
  • NRZ-OOK Transmission with GeSi EAM
  • Xin Yin
  • Guy Torfs
  • Johan Bauwelinck --
  • Liang Zhang
  • Xin Yin
  • Datacenters and Photonic Integrated Circuits
  • Demis D. John
  • Grant Brodnik
  • Sarat Gundavarapu
  • Renan L. Moreira
  • Michael Belt
  • Taran Huffman
  • Daniel J. Blumenthal
  • 11.2.
  • InP, Si, and Si3N4 Waveguide Platforms
  • Guy Torfs
  • Demis D. John
  • Grant Brodnik
  • Sarat Gundavarapu
  • Renan L. Moreira
  • Michael Belt
  • Taran Huffman
  • Daniel J. Blumenthal
  • 11.3.
  • Ultra-Low Loss Si3N4/SiO2 Platform
  • Demis D. John
  • Johan Bauwelinck
  • Grant Brodnik
  • Sarat Gundavarapu
  • Renan L. Moreira
  • Michael Belt
  • Taran Huffman
  • Daniel J. Blumenthal
  • 11.4.
  • Integration Building Blocks on the ULL Silicon Nitride Platform
  • Sarat Gundavarapu
  • Renan L. Moreira
  • References
  • Michael Belt
  • Taran Huffman
  • Daniel J. Blumenthal
  • Demis D. John
  • Grant Brodnik
  • 11.4.1.
  • Available PIC Platforms
  • Demis D. John
  • Grant Brodnik
  • Sarat Gundavarapu
  • Xin Yin
  • Renan L. Moreira
  • Michael Belt
  • Taran Huffman
  • Daniel J. Blumenthal
  • 11.5.
  • Ultra-Low Loss PIC Components for Datacom
  • Demis D. John
  • Grant Brodnik
  • Sarat Gundavarapu
  • Renan L. Moreira
  • Guy Torfs
  • Michael Belt
  • Taran Huffman
  • Daniel J. Blumenthal
  • 11.5.1.
  • Low-Loss PICs and Optical Delays
  • Demis D. John
  • Grant Brodnik
  • Sarat Gundavarapu
  • Renan L. Moreira
  • Michael Belt
  • Johan Bauwelinck
  • Taran Huffman
  • Daniel J. Blumenthal
  • 11.5.2.
  • Integrated Dispersion Compensation
  • Demis D. John
  • Grant Brodnik
  • Sarat Gundavarapu
  • Renan L. Moreira
  • Michael Belt
  • Taran Huffman
  • 9.1.
  • Daniel J. Blumenthal
  • 11.5.2.1.
  • Design of an Integrated Dispersion Compensator
  • Demis D. John
  • Grant Brodnik
  • Sarat Gundavarapu
  • Renan L. Moreira
  • Michael Belt
  • Taran Huffman
  • Daniel J. Blumenthal
  • Introduction
  • 11.5.2.2.
  • Demonstration of 40 Gbps NRZ-OOK Dispersion Compensation
  • Demis D. John
  • Grant Brodnik
  • Sarat Gundavarapu
  • Renan L. Moreira
  • Michael Belt
  • Taran Huffman
  • Daniel J. Blumenthal
  • 11.5.2.3.
  • Yuya Yamaguchi
  • Demonstration of 40 Gbps PAM-4 Dispersion Compensation
  • Demis D. John
  • Grant Brodnik
  • Sarat Gundavarapu
  • Renan L. Moreira
  • Michael Belt
  • Taran Huffman
  • Daniel J. Blumenthal
  • 11.5.3.
  • Grating Filters
  • Contents note continued:
  • Hirochika Nakajima
  • Taran Huffman
  • Michael Belt
  • Renan L. Moreira
  • Sarat Gundavarapu
  • Grant Brodnik
  • Demis D. John
  • Daniel J. Blumenthal
  • 11.5.4.
  • Ring Resonator Filters
  • Grant Brodnik
  • 9.2.
  • Sarat Gundavarapu
  • Renan L. Moreira
  • Michael Belt
  • Taran Huffman
  • Daniel J. Blumenthal
  • Demis D. John
  • 11.5.5.
  • High-Extinction Filters
  • Taran Huffman
  • Daniel J. Blumenthal
  • Physical Properties of LN (LiNbO3) Crystal
  • Michael Belt
  • Renan L. Moreira
  • Sarat Gundavarapu
  • Grant Brodnik
  • Demis D. John
  • 11.5.6.
  • C-band Lasers on the Si3N4 Platform
  • Daniel J. Blumenthal
  • Taran Huffman
  • Michael Belt
  • Hirochika Nakajima
  • Renan L. Moreira
  • Sarat Gundavarapu
  • Grant Brodnik
  • Demis D. John
  • 11.6.
  • Silicon-Nitride Waveguide Design
  • Taran Huffman
  • Daniel J. Blumenthal
  • Michael Belt
  • Renan L. Moreira
  • Yuya Yamaguchi
  • Sarat Gundavarapu
  • Grant Brodnik
  • Demis D. John
  • 11.7.
  • Summary
  • Daniel J. Blumenthal
  • Taran Huffman
  • Michael Belt
  • Renan L. Moreira
  • Sarat Gundavarapu
  • 9.3.
  • Grant Brodnik
  • Demis D. John
  • References
  • Taran Huffman
  • Daniel J. Blumenthal
  • Michael Belt
  • Renan L. Moreira
  • Sarat Gundavarapu
  • Grant Brodnik
  • Demis D. John
  • Low-loss Ti-diffused Waveguides on LN Since 1974
  • 12.1.
  • Introduction
  • Steve Yao
  • Wajih Daab
  • Gang He
  • Daniel Gariepy
  • 12.2.
  • Polarization Related Tests
  • Steve Yao
  • Daniel Gariepy
  • Hirochika Nakajima
  • Gang He
  • Wajih Daab
  • 12.2.1.
  • Polarization Mode Dispersion (PMD) Measurement
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Wajih Daab
  • 12.2.2.
  • Polarization Dependent Loss (PDL) Measurement
  • Yuya Yamaguchi
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Wajih Daab
  • 12.2.3.
  • PDR Measurement of Receivers
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Wajih Daab
  • 9.4.
  • 12.2.4.
  • PDL Measurement of Fiber Optic Link
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Wajih Daab
  • 12.2.5.
  • Measuring In-band OSNR by DOP Measurement
  • Steve Yao
  • Daniel Gariepy
  • 8.6.
  • Mach-Zehnder (MZ) Guided-wave Circuit with Y-branches on LN
  • Gang He
  • Wajih Daab
  • 12.2.6.
  • Polarization Emulation for Non-coherent and Coherent Systems
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Wajih Daab
  • 12.3.
  • Optical Signal-to-Noise Ratio Measurement
  • Hirochika Nakajima
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Wajih Daab
  • 12.3.1.
  • Measuring OSNR with an OSA
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Wajih Daab
  • Yuya Yamaguchi
  • 12.4.
  • Characterization of Optical Vector-Modulated Signals
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Wajih Daab
  • 12.4.1.
  • Constellation and IQ Diagrams for Vector-Modulated Signal
  • Steve Yao
  • Daniel Gariepy
  • 9.5.
  • Gang He
  • Wajih Daab
  • 12.4.2.
  • Definitions of EVM, RMS-EVM and TR-EVM
  • Wajih Daab
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • 12.4.3.
  • Relationships between EVMRMS, Q-Factor, OSNR and BER
  • Velocity Matching Between Lightwave and Electric Signal
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Wajih Daab
  • 12.4.4.
  • Characterization of Transmitter Impairments
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Wajih Daab
  • Hirochika Nakajima
  • 12.5.
  • Conclusion
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Wajih Daab
  • References
  • Steve Yao
  • Daniel Gariepy
  • Gang He
  • Yuya Yamaguchi
  • Wajih Daab
  • 13.1.
  • Introduction
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • 13.1.1.
  • 9.6.
  • Challenges for Short-reach Optical Systems
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • 13.1.1.1.
  • Cost
  • Kangping Zhong
  • Stabilization of LN-MZM Operation
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • 13.1.1.2.
  • Form factor
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Hirochika Nakajima
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • 13.1.1.3.
  • Latency
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • SM LW-VCSEL EDB Links
  • Yuya Yamaguchi
  • Jiahao Huo
  • 13.1.2.
  • Different Types of Short-reach Systems
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • 13.1.2.1.
  • 9.7.
  • Server-to-server or Intra-data-center links
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • 13.1.2.2.
  • Inter data-center links
  • Alan Pak Tao Lau
  • External Modulation by LN-MZM Accompanied with EDFA Repeating
  • Chao Lu
  • Jiahao Huo
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • 13.1.2.3.
  • Extended Reach Inter-data-center, Access, and Metro Links
  • Kangping Zhong
  • Xian Zhou
  • Jiahao Huo
  • Hirochika Nakajima
  • Alan Pak Tao Lau
  • Chao Lu
  • Li Zeng
  • 13.2.
  • Modulation Formats for Short-reach Systems
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Yuya Yamaguchi
  • Jiahao Huo
  • 13.2.1.
  • Pulse Amplitude Modulation (PAM)
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • 9.8.
  • Vector Modulation with LN-MZM for Digital Coherent Optical Communications
  • Hirochika Nakajima
  • Yuya Yamaguchi
  • 9.9.
  • Xin Yin
  • Current Status of LN-MZM and Future Potential
  • Hirochika Nakajima
  • Yuya Yamaguchi
  • 9.10.
  • Summary
  • Hirochika Nakajima
  • Yuya Yamaguchi
  • References
  • Hirochika Nakajima
  • Yuya Yamaguchi
  • Guy Torfs
  • 10.1.
  • Introduction
  • Radhakrishnan Nagarajan
  • Mark Filer
  • 10.2.
  • Datacenter Interconnect-Edge
  • Radhakrishnan Nagarajan
  • Mark Filer
  • 10.3.
  • Switch Pluggable 100Gbit/s DWDM Module
  • Johan Bauwelinck
  • Radhakrishnan Nagarajan
  • Mark Filer
  • 10.4.
  • PAM4 DSP ASIC
  • Radhakrishnan Nagarajan
  • Mark Filer
  • 10.5.
  • Silicon Photonics
  • Radhakrishnan Nagarajan
  • Mark Filer
  • 8.7.
  • 10.6.
  • Module and Transmission Performance
  • Radhakrishnan Nagarajan
  • Mark Filer
  • 10.7.
  • Live Datacenter Deployments
  • Radhakrishnan Nagarajan
  • Mark Filer
  • 10.8.
  • Evolution to Switch Pluggable 400-Gbit/s DWDM Module
  • Conclusion
  • Radhakrishnan Nagarajan
  • Mark Filer
  • 10.9.
  • Conclusion
  • Radhakrishnan Nagarajan
  • Mark Filer
  • References
  • Radhakrishnan Nagarajan
  • Mark Filer
  • 11.1.
  • Chao Lu
  • Jiahao Huo
  • 13.2.3.
  • Discrete Multi-tone (DMT) Modulation
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • /
  • 13.2.4.
  • Performance Comparison of Modulation Formats
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • 13.2.5.
  • Complexity Comparison of Modulation Formats
  • Jiahao Huo
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • 13.2.6.
  • Recent Experiment on High-Speed Short-reach Transmission Systems
  • Kangping Zhong
  • Xian Zhou
  • 13.2.2.
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • 13.3.
  • Digital Signal Processing for Short-reach Systems
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Carry-less Amplitude and Phase (CAP) Modulation
  • Chao Lu
  • Jiahao Huo
  • 13.3.1.
  • Feed-forward Equalizer (FFE)
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • Kangping Zhong
  • 13.3.2.
  • Decision Feedback Equalizer (DFE)
  • Xian Zhou
  • Jiahao Huo
  • Kangping Zhong
  • Chao Lu
  • Li Zeng
  • Alan Pak Tao Lau
  • 13.3.3.
  • Direct Detection Faster-than Nyquist (DD-FTN)
  • Xian Zhou
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • 13.3.4.
  • Volterra-series Based Nonlinear Equalizer (VNLE)
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo --
  • Alan Pak Tao Lau
  • Jiahao Huo
  • Intensity-only POL-MUX-DM Coherent System
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.2.2.
  • Complex DM Model
  • Di Che
  • An Li
  • 13.4.1.
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.2.3.
  • 100-Gb/s CDM Transmission Over 1600-km SMF
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • Stokes-vector Direct Detection (SV-DD) Receiver
  • 14.3.
  • Polarization Modulation in Stokes Space
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.3.1.
  • Stokes-space Modulation
  • Di Che
  • Kangping Zhong
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.3.2.
  • Universal MIMO Equalization in Stokes Space
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xian Zhou
  • Xi Chen
  • 14.3.3.
  • Self-coherent SSM
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.3.4.
  • Multi-Dimensional IM in Stokes Space
  • Li Zeng
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.4.
  • Noncoherent Polarization Multiplexing
  • Di Che
  • An Li
  • William Shieh
  • Alan Pak Tao Lau
  • Qian Hu
  • Xi Chen
  • 14.4.1.
  • Degree of Coherence in POL-MUX Transmitter
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.4.2.
  • Chao Lu
  • Noncoherent POL-MUX Schemes
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.5.
  • Summary
  • Di Che
  • An Li
  • Jiahao Huo
  • William Shieh
  • Qian Hu
  • Xi Chen
  • References
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 15.1.
  • 13.4.2.
  • Introduction
  • Glenn A. Wellbrock
  • Tiejun J. Xia
  • 15.2.
  • Why Optical Coherent Transmission?
  • Glenn A. Wellbrock
  • Tiejun J. Xia
  • 15.3.
  • Optical Transport Network with Coherent Transmission
  • Glenn A. Wellbrock
  • Contents note continued:
  • 2-Dimensional (2D) PDM-DD System Based on SV-DD Receiver
  • Tiejun J. Xia
  • 15.4.
  • What's Next for Optical Transport Network?
  • Glenn A. Wellbrock
  • Tiejun J. Xia
  • 15.5.
  • Coherent Transport Technology Development by Network Operators
  • Glenn A. Wellbrock
  • Tiejun J. Xia
  • 15.6.
  • Kangping Zhong
  • Datacenter Connections and Coherent Transport Networks
  • Glenn A. Wellbrock
  • Tiejun J. Xia
  • 15.7.
  • Conclusions
  • Glenn A. Wellbrock
  • Tiejun J. Xia
  • References
  • Glenn A. Wellbrock
  • Tiejun J. Xia
  • Xian Zhou
  • 16.1.
  • Introduction
  • Jung Han Choi
  • 16.2.
  • IC Design for Low Power Consumption
  • Jung Han Choi
  • 16.2.1.
  • Design Requirements
  • Jung Han Choi
  • 16.2.2.
  • Li Zeng
  • IC Architectures for Low Power Consumption
  • Jung Han Choi
  • 16.2.3.
  • Driver-IC Design
  • Jung Han Choi
  • 16.2.3.1.
  • Unit-cell design
  • Jung Han Choi
  • 16.2.3.2.
  • Circuit Simulations
  • Alan Pak Tao Lau
  • Jung Han Choi
  • 16.3.
  • Co-design and Electro-optical Simulation
  • Jung Han Choi
  • 16.3.1.
  • Low-power CoC Design
  • Jung Han Choi
  • 16.3.2.
  • Co-simulation of Driver-IC with EML
  • Jung Han Choi
  • Chao Lu
  • 16.3.2.1.
  • Electrical Time-domain Simulations
  • Jung Han Choi
  • 16.3.2.2.
  • Electro-optical Time-domain Simulations
  • Jung Han Choi
  • 16.4.
  • Measurements
  • Jung Han Choi
  • 16.4.1.
  • Jiahao Huo
  • EO Measurements
  • Jung Han Choi
  • 16.4.2.
  • Transmission Experiments
  • Jung Han Choi
  • 16.5.
  • Conclusion and Perspective
  • Jung Han Choi
  • References
  • Jung Han Choi
  • 13.4.3.
  • 3-Dimensional (3D) PDM-DD System Based on SV-DD Receiver
  • Kangping Zhong
  • 13.4.
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • 13.5.
  • Conclusion
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Polarization Division Multiplexed Transmission for Short-reach Systems
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • References
  • Kangping Zhong
  • Xian Zhou
  • Li Zeng
  • Alan Pak Tao Lau
  • Chao Lu
  • Jiahao Huo
  • Kangping Zhong
  • 14.1.
  • Optical Detection with Polarization Diversity
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.1.1.
  • Need of Polarization-Diversity Detection
  • Di Che
  • Xian Zhou
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.1.2.
  • Automatic Polarization Control
  • An Li
  • Xi Chen
  • Di Che
  • William Shieh
  • Li Zeng
  • Qian Hu
  • 14.1.3.
  • Polarization-Diversity Detection in Jones Space
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.1.4.
  • Barrier of Self-Polarization Diversity
  • Alan Pak Tao Lau
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.1.5.
  • Polarization-Diversity Detection in Stokes Space
  • Di Che
  • An Li
  • William Shieh
  • Chao Lu
  • Qian Hu
  • Xi Chen
  • 14.2.
  • Direct Modulation with Coherent Receiver
  • Di Che
  • An Li
  • William Shieh
  • Qian Hu
  • Xi Chen
  • 14.2.1.
Control code
MSTDDA5493980
Dimensions
unknown
Extent
1 online resource ( 760 pages.):
Form of item
online
Isbn
9788793609211
Media category
computer
Media MARC source
rdamedia
Media type code
  • c
Reproduction note
Electronic reproduction.
Specific material designation
remote

Library Locations

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