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Handbook of Optoelectronics, Second Edition (Three-Volume Set) 2nd edition [Multiple-component retail product]

Edited by (Emeritus Professor, University of Southampton), Edited by (Beckman Laser Institute and Medical Clinic, University of California, Irvine, USA)
  • Formatas: Multiple-component retail product, 2192 pages, aukštis x plotis: 254x178 mm, weight: 4853 g, 137 Tables, black and white; 1340 Illustrations, black and white, Contains 3 hardbacks
  • Serija: Series in Optics and Optoelectronics
  • Išleidimo metai: 31-Oct-2017
  • Leidėjas: CRC Press Inc
  • ISBN-10: 1482241722
  • ISBN-13: 9781482241723
Kitos knygos pagal šią temą:
Handbook of Optoelectronics, Second Edition (Three-Volume Set) 2nd editionDidesnis paveikslėlis
  • Formatas: Multiple-component retail product, 2192 pages, aukštis x plotis: 254x178 mm, weight: 4853 g, 137 Tables, black and white; 1340 Illustrations, black and white, Contains 3 hardbacks
  • Serija: Series in Optics and Optoelectronics
  • Išleidimo metai: 31-Oct-2017
  • Leidėjas: CRC Press Inc
  • ISBN-10: 1482241722
  • ISBN-13: 9781482241723
Kitos knygos pagal šią temą:
Pastovi nuoroda: https://www.kriso.lt/db/9781482241723.html
Handbook of Optoelectronics offers a self-contained reference from the basic science and light sources to devices and modern applications across the entire spectrum of disciplines utilizing optoelectronic technologies. This second edition gives a complete update of the original work with a focus on systems and applications.

No other resource in the field comes close to its breadth and depth, with contributions from leading industrial and academic institutions around the world. Whether used as a reference, research tool, or broad-based introduction to the field, the Handbook offers everything you need to get started.

John P. Dakin, PhD, is professor (emeritus) at the Optoelectronics Research Centre, University of Southampton, UK.

Robert G. W. Brown, PhD, is chief executive officer of the American Institute of Physics, and an adjunct full professor in the Beckman Laser Institute and Medical Clinic at the University of California, Irvine.
Series Preface ix
Introduction to the Second Edition xi
Introduction to the First Edition xiii
Editors xv
Contributors xvii
PART I BASIC CONCEPTS
1(196)
1 An introduction to optoelectronics
3(18)
Alan Rogers
Vincent Handerek
2 Introduction to optical materials
21(20)
Neil J. Ross
3 Incandescent, discharge, and arc lamp sources
41(24)
David O. Wharmby
4 Detection of optical radiation
65(60)
Antoni Rogalski
Zbigniew Bielecki
Janusz Mikolajczyk
5 Propagation along optical fibers and waveguides
125(50)
John Love
6 Introduction to lasers and optical amplifiers
175(22)
William S. Wong
Chien-Jen Chen
Yan Sun
PART II ADVANCED CONCEPTS
197(106)
7 Advanced optics
199(66)
Alan Rogers
Vincent Handerek
8 Basic concepts in photometry, radiometry, and colorimetry
265(16)
Yoshi Ohno
9 Nonlinear and short pulse effects
281(22)
Gunter Steinmeyer
PART III OPTOELECTRONIC DEVICES AND TECHNIQUES
303
10 Light emitting diodes (LEDs)
305(44)
Klaus Streubel
11 Semiconductor lasers
349(46)
Jayanta Mukherjee
Stephen J. Sweeney
12 Optical detectors and receivers
395(36)
Hidehiro Kume
13 Optical fiber devices
431(26)
Suzanne Lacroix
Xavier Daxhelet
14 Optical modulators
457(58)
Nadir Dagli
15 Optical amplifiers
515(30)
Johan Nilsson
Jesper Laegsgaard
Anders Bjarklev
16 Ultrafast optoelectronics
545(28)
Gunter Steinmeyer
17 Integrated optics
573(60)
Nikolaus Boos
Christian Lerminiaux
18 Infrared devices and techniques
633(54)
Antoni Rogalski
Krzysztof Chrzanowski
19 Organic light emitting devices
687(24)
Martin Grell
20 Microstructured optical fibers
711(30)
Jesper Laegsgaard
Anders Bjarklev
Tanya Monro
21 Engineered optical materials
741(18)
Peter G. R. Smith
Corin B. E. Gawith
22 Silicon photonics
759(26)
Sasan Fathpour
23 Nanoplasmonic optoelectronics
785
Robert G. W. Brown
Index 813
Series Preface ix
Preface xi
Introduction to the Second Edition xiii
Editors xv
Contributors xvii
PART I OPTOELECTRONICS IN INFRASTRUCTURE
1(48)
1 Overview of fiber optic sensing technologies for structural health monitoring
5(14)
Daniele Inaudi
2 Distributed acoustic sensing for infrastructure
19(10)
Stuart Russell
3 Intelligent infrastructure: Automatic number plate recognition for smart cities
29(14)
Benjamin Watson
4 Optoelectronics for control of city transport
43(6)
David Parkyns
PART II ON-VEHICLE APPLICATIONS IN TRANSPORT
49(26)
5 Optoelectronics for automobiles, vans, and trucks
55(10)
John P. Dakin
6 360° camera systems for surveillance and security
65(10)
Gareth J. Edwards
PART III OPTOELECTRONICS FOR SECURITY AND SURVEILLANCE
75(8)
7 Applications of distributed acoustic sensing for security and surveillance
79(4)
Stuart Russell
PART IV EARTH RESOURCES AND ENVIRONMENTAL MONITORING
83(56)
8 Overview of earth observation from satellites
89(8)
Greg Blackman
Jessica Rowbury
9 Satellite-based land monitoring
97(6)
Gerardo Lopez-Saldana
Debbie Clifford
10 Optical remote sensing of marine, coastal, and inland waters
103(12)
Valborg Byfield
11 Oceanographic and aquatic: Applications of optic sensing technologies
115(14)
Matt Mowlem
Alex Beaton
Gregory Slavik
12 Monitoring of volcanic eruptions: An example of the application of optoelectronics instrumentation in atmospheric science
129(10)
Barbara J. Brooks
PART V MILITARY APPLICATIONS
139(44)
13 Military optoelectronics
145(38)
Hillary G. Sillitto
PART VI INDUSTRIAL APPLICATIONS
183(76)
14 Optical gas-sensing methods for industry
191(16)
Jane Hodgkinson
John P. Dakin
15 Laser applications in industry
207(6)
Paul Harrison
16 Laser and LED systems for industrial metrology and spectroscopy for industrial uses
213(14)
John P. Dakin
17 3D Printing applications
227(8)
Candice Majewski
18 Fiber optical sensors for monitoring industrial gas turbines
235(10)
Ralf D. Pechstedt
David Hemsley
19 Raman gas spectroscopy
245(14)
Andreas Knebl
Jurgen Popp
Torsten Frosch
PART VII OIL, GAS, AND MINERAL EXPLORATION AND REFINING
259(58)
20 Fiber optics in the oil and gas industry
263(24)
Andre Franzen
21 Oilfield production monitoring with fiber-optic sensors
287(12)
Philip Nash
22 Applications of visible to near-infrared spectroscopy for downhole fluid analysis inside oil and gas wellbores
299(8)
Go Fujisawa
Oliver C. Mullins
Tsutomu Yamate
23 Mid-infrared spectroscopy for future oil, gas, and mineral exploration
307(10)
Christian M. Muller
Florian Rauh
Thomas Schadle
Matthias Schwenk
Robert Stach
Boris Mizaikoff
Bobby Pejcic
PART VIII APPLICATIONS IN ENERGY GENERATION AND DISTRIBUTION
317(18)
24 Applications of electricity generation by solar panels
323(10)
Fernando Araujo de Castro
25 Advantages of fiber optical sensors for power generation
333(2)
Ralf D. Pechstedt
David Hemsley
PART IX APPLICATIONS FOR MEDICINE, HEALTH MONITORING, AND BIOTECHNOLOGY
335(54)
26 Medical applications of photonics
343(22)
Constantinos Pitris
Tuan Vo-Dinh
R. Eugene Goodson
Susie E. Goodson
27 Breath analysis with mid-infrared diagnostics
365(12)
Vjekoslav Kokoric
Erhan Tutuncu
Felicia Seichter
Andreas Wilk
Paula R. Fortes
Ivo M. Raimundo
Boris Mizaikoff
28 Fiber optic manometry catheters for in vivo monitoring of peristalsis in the human gut
377(6)
John Arkwright
Phil Dinning
29 Optical coherence tomography in medicine
383(6)
Michael A. Marcus
PART X HOME AND MOBILE PORTABLE EQUIPMENT APPLICATIONS
389(20)
30 Applications for home and mobile portable equipment
397(12)
John P. Dakin
Michael A. Marcus
PART XI FREE SPACE OPTICAL COMMUNICATIONS
409(20)
31 Optical communications through free space
413(16)
Dominic O'Brien
Index 429
John P. Dakin, PhD, is Professor (Emeritus) at the Optoelectronics Research Centre, University of Southampton. He received the B.Sc. and Ph.D. degrees from Southampton University, U.K., and remained there as a Research Fellow until 1973 where he supervised research and development of optical fiber sensors and other optical measurement instruments. He then spent two years in Germany at AEG Telefunken, 12 years at Plessey, UK, and two years with York Limited/York Biodynamics before returning to Southampton University. He has authored over 150 technical and scientific papers, and over 120 patent applications. He was previously a Visiting Professor at Strathclyde University, UK.

Dr. Dakin has won a number of awards, including "Inventor of the Year" for Plessey Electronic Systems Limited, the Electronics Divisional Board Premium of 1EE. Earlier, he won open scholarships to both Southampton and Manchester Universities. He has also been responsible for a number of key electro-optic developments. These include the sphere lens optical fiber connector, the first WDM optical shaft encoder, the Raman optical fiber distributed temperature sensor, the first realization of a fiber-optic passive hydrophone array sensor and the Sagnac location method described here, plus a number of novel optical gas sensing methods.

Robert G. W. Brown, PhD, is chief executive officer of the American Institute of Physics.

He received his PhD in engineering from the University of Surrey and his BS in physics from Royal Holloway College at the University of London. He was previously an applied physicist at Rockwell Collins, where he carried out research in photonic ultra-fast computing, optical detectors, and optical materials. Previously, he was an advisor to the UK government, and international and editorial director of the Institute of Physics. He is an elected member of the European Academy of the Sciences and Arts (Academia Europaea) and special professor at the University of Nottingham in the UK. He also retains a position as adjunct full professor at the University of California, Irvine, in the Beckman Laser Institute and Medical Clinic, and as visiting professor in the Department of Computer Science. He has authored more than 120 articles in peer-reviewed journals and holds 34 patents, several of which have been successfully commercialized.

Dr. Brown has been recognized for his entrepreneurship with the UK Ministry of Defence Prize for Outstanding Technology Transfer, a prize from Sharp Corporation (Japan) for his novel laser-diode invention, and, together with his team at the UK Institute of Physics, a Queens Award for Enterprise, the highest honor bestowed on a UK company. He has guest edited several special issues of Applied Physics, and was consultant to many companies and government research centers in the USA and UK. He is a Series Editor of the CRC Press Series in Optics and Optoelectronics.