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In this book we will discuss both the operating principles and performance limits of a wide range of device technologies, and the technological requirements of applications. We will identify close synergies where technology capabilities and application requirements are closely aligned, and opportunities for generic optical frequency combs where multiple solutions and applications exist simultaneously. The main topics to be covered will include:(i) Different sources and methods of optical frequency combs generation including mode-locked lasers, optical resonators, opto-electronics, and nonlinear fibres. (ii) Applications of optical frequency combs in different technologies including sensing, spectroscopy, metrology, distance ranging and optical communications. (iii) Blue-sky novel physical concepts and promising future research directions for the field. With this book we aim at showcasing top level advances by key players in a multifaceted research ecosystem, and at the same time at providing a valuable service to our research community, by offering a comprehensive review which, at the same time, highlights challenges to be solved and promising future directions. This book will be a valuable resource for academics and researchers working in optical frequency combs, and more broadly in photonics and laser physics. It will also be of interest to postgraduate and graduate students of photonics and laser physics.

Key Features:

?????????????? Edited by authorities in the field, with chapter contributions from subject area experts.

?????????????? Up-to-date with the latest technological developments,applications, and research from the field.

?????????????? The first book to provide a modern overview of the field since 2005.

Andrew Ellis received the B.Sc. degree in physics with a minor in mathematics from the University of Sussex, Brighton, U.K., in 1987. He received the Ph.D. degree in electronic and electrical engineering from The University of Aston in Birmingham, Birmingham, U.K., in 1997 for his study on all optical networking beyond 10 Gbit/s. He previously worked for British Telecom Research Laboratories as a Senior Research Engineer investigating the use of optical amplifiers and advanced modulation formats in optical networks and the Corning Research Centre as a Senior Research Fellow where he led activities in optical component characterization. He headed the Transmission and Sensors Group at the Tyndall National Institute in Cork, Ireland, where he was also a member of the Department of Physics, University College Cork. He research interests include the evolution of core and metronetworks, and the application of photonics to sensing. He is now Professor of Optical Communications at Aston University where he is also deputy director of the Institute of Photonics Technologies (AIPT) group. He has published over 200 journal papers and over 25 patents in the field of photonics, primarily targeted at increasing capacity, reach and functionality in the optical layer. Prof. Ellis is a Fellow of the Optical Society of America. He served for 6 years as an associate editor of the journal Optics Express. He has twice been a Technical Program Committee PC member for OFC. Prof Ellis was also a member of the Technical Program Committee of ECOC from 2004 to 2018 serving as overall TPC chair for ECOC 2019.

Auro Perego received a BSc and a MSc in Physics from Universita dell’Insubria (Como, Italy) and a PhD degree in Electrical Engineering from Aston University (Birmingham, UK) in 2018. He is currently a Royal Academy of Engineering Research Fellow ? with a project on optical frequency combs ? at the Aston Institute of Photonic Technologies, Aston University, where he is building his independent research group. His main research interests live at the interface between applied physics and photonic engineering and include: the investigation of novel techniques for optical frequency combs generation in optical resonators, the physics of modelocking in semiconductor and fibre lasers, parametric amplification in nonlinear waveguides, optical sensing, the study of instabilities and solitons in photonic systems. His research results have been published in top level journals in the field such as Nature Communications, Light:Science & Applications, Optica and Physical Review Letters amongst others. He has been a Technical Program Committee member for CLEO US 2022 and 2023 and for Photon UK 2022

In this book we will discuss both the operating principles and performance limits of a wide range of device technologies, and the technological requirements of applications.

정보제공 :

Introduction. Chapter 1: Optical frequency combs from supercontinuum?generation in integrated?photonics. Chapter 2: Integrated lithium niobate?optical frequency combs. Chapter 3: Soliton Frequency Combs in Microresonators. Chapter 4: Semiconductor Device based Optical Frequency Comb Generation. Chapter 5: Quantum Cascade Laser?frequency combs. Chapter 6: Fibre-based Optical?Frequency Combs. Chapter 7: Optical frequency combs in fibre resonators. Chapter 8: All-fibre?frequency agile triple-frequency comb light source. Chapter 9: Spectroscopy with?electro-optic dual?frequency combs. Chapter 10: Optical Frequency Combs in the?2?μm Waveband for Dual Comb?Spectroscopy. Chapter 11: Dual-Comb Ranging. Chapter 12: Dual-comb microscopy. Chapter 13: Electro-Optic Sampling-Based Timing?and Synchronization with?Optical?Frequency Combs. Chapter 14: Optical Frequency Combs Applications for Synchronous Transmission. Chapter 15: Integrated optical frequency combs and their applications - An industry perspective. Chapter 16: Optical frequency combs for optical clocks.

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