Dramatic increases in processing power have rapidly scaled on-chip aggregate bandwidths into the Tb/s range. This necessitates a corresponding increase in the amount of data communicated between chips, so as not to limit overall system performance. To meet the increasing demand for interchip communication bandwidth, researchers are investigating the use of high-speed optical interconnect architectures. Unlike their electrical counterparts, optical interconnects offer high bandwidth and negligible frequency-dependent loss, making possible per-channel data rates of more than 10 Gb/s. High-Speed Photonics Interconnects explores some of the groundbreaking technologies and applications that are based on photonics interconnects.
From the Evolution of High-Speed I/O Circuits to the Latest in Photonics Interconnects Packaging and Lasers
Featuring contributions by experts from academia and industry, the book brings together in one volume cutting-edge research on various aspects of high-speed photonics interconnects. Contributors delve into a wide range of technologies, from the evolution of high-speed input/output (I/O) circuits to recent trends in photonics interconnects packaging. The book discusses the challenges associated with scaling I/O data rates and current design techniques. It also describes the major high-speed components, channel properties, and performance metrics. The book exposes readers to a myriad of applications enabled by photonics interconnects technology.
Learn about Optical Interconnect Technologies Suitable for High-Density Integration with CMOS Chips
This richly illustrated work details how optical interchip communication links have the potential to fully leverage increased data rates provided through complementary metal-oxide semiconductor (CMOS) technology scaling at suitable power-efficiency levels. Keeping the mathematics to a minimum, it gives engineers, researchers, graduate students, and entrepreneurs a comprehensive overview of the dynamic landscape of high-speed photonics interconnects.
"This book provides reviews of a topic of increasing importance: high-speed optical interconnects. The coverage combines topics not often assembled in book format, and the authors are active researchers in the field. It saves the reader arduous hours that would otherwise be spent searching and reviewing reams of published literature to get up to speed on these rapidly evolving topics."
—Tony Chan Carusone, Department of Electrical and Computer Engineering, University of Toronto, Canada
"… a very good overview of the most cutting-edge interconnect technologies as they apply to computer and communication networks. … The importance now being placed on interconnects as part of an integrated solution for a better and more prolific information processing paradigm is an absolute necessity. Not only because the of the overall power consumption issues we face, but because a world-wide, exponentially expanding interconnect medium will ultimately unite our thoughts, goals and expressions as a global society. This will allow ever newer architectures and models to be conceived, perhaps based on biological systems - where we have consistently found that (our) whole is greater than the sum of (our) parts."
—David Rolston, Reflex Photonics Inc., Quebec, Canada
Energy-Efficient Photonic Interconnects for Computing Platforms
Odile Liboiron-Ladouceur, Nicola Andriolli, Isabella Cerutti, Piero Castoldi, and Pier Giorgio Raponi
Low-Loss, High-Performance Chip-to-Chip Electrical Connectivity Using Air-Clad Copper Interconnects
Rohit Sharma, Rajarshi Saha, and Paul A. Kohl
Silicon Photonic Bragg Gratings
Xu Wang, Wei Shi, and Lukas Chrostwoski
Lasers for Optical Interconnects
Vertical-Cavity Surface-Emitting Lasers for Interconnects
Werner H.E. Hofmann
High-Speed Photodiodes and Laser Power Converters for the Applications of Green Optical Interconnect
Quantum-Dot Nanophotonics for Photodetection
Ludan Huang and Lih Y. Lin
Rolled-Up Semiconductor Tube Optical Cavities
Pablo Bianucci, M. Hadi Tavakoli Dastjerdi, Mehrdad Djavid, and Zetian Mi