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国外电子与通信教材系列:光电子学与光子学·原理与实践(第2版)(英文版) 定 价:¥79 中 教 价:¥60.83 (7.70折) 库 存 数: 0
《国外电子与通信教材系列:光电子学与光子学·原理与实践(第2版)(英文版)》的主要内容包括光的波动特性,介质波导和光纤,半导体科学基础和LED,光放大器和激光器,光探测器和图像传感器,光的偏振和调制等。每个章节除了基本的题材,还给出一些附加主题适当介绍先进技术和产品化光电子器件实例,扩大和深化读者对基本内容的理解。
《国外电子与通信教材系列:光电子学与光子学·原理与实践(第2版)(英文版)》力求采用尽可能少的数学推导而强调通过物理概念来说明原理,提供了许多例题,使得课本概念与实际器件相联系,也提供了大量的练习题。
《国外电子与通信教材系列:光电子学与光子学·原理与实践(第2版)(英文版)》是在光电子和光子器件领域的一个最新的适合本科阶段的入门教科书,《国外电子与通信教材系列:光电子学与光子学·原理与实践(第2版)(英文版)》力求采用尽可能少的数学推导而强调通过物理概念来说明原理,提供了许多例题,使得课本概念与实际器件相联系,也提供了大量的练习题。 《国外电子与通信教材系列:光电子学与光子学·原理与实践(第2版)(英文版)》有非常清楚的文字和图,明确的解释使得问题很容易理解。与众不同的另一点是它既覆盖了光子学基本面,又具有较深的深度,包含了具体的器件设计和工程应用知识,将光子学和光电子基本理论与各种光子学应用相结合。所以这是一本对本科生、研究生以及光电工程师都非常有用的教科书。
Preface
The first edition of this book was written more than 12 years ago. At the time it was meant as an easy-to-read book for third-year engineering or applied physics undergraduate students;it emphasized qualitative explanations and relied heavily on intuitive derivations. As things turned out, the first edition ended up being used in fourth-year elective classes, and even in graduate courses on optoelectronics. Many of the instructors teaching at that level rightly needed better derivations, more rigor, better explanations, and, of course, many more topics and problems. We have all at one time or another suffered from how wrong some intuitive short-cut derivations can be. The second edition was therefore prepared by essentially rewriting the text almost from scratch with much better rigor and explanations, but without necessarily dwelling on mathematical details. Many new exciting practical examples have been introduced, and numerous new problems have been added. The book also had to be totally modernized given that much had happened in the intervening 12 years that deserved being covered in an undergraduate course. Features, Changes, and Revisions in the Second Edition The second edition represents a total revision of the first edition, with numerous additional features and enhancements. All chapters have been totally revised and extended. Numerous modern topics in photonics have been added to all the chapters. There are Additional Topics that can be covered in more advanced courses, or in courses that run over two semesters. There are many more new examples and solved prblems within chapters, and many more practical end-of-chapter problems that start from basic concepts and build up onto advanced applications. Nearly all the illustrations and artwork in the first edition have been revised and redrawn to better reflect the concepts. Numerous new illustrations have been added to convey the concepts as clearly as possible. Photographs have been added, where appropriate, to enhance the readability of the book and to illustrate typical modern photonic/optoelectronic devices. The previous edition’s Chapter 7 on photovoltaics has been incorporated into this edition’s Chapter 5 as an Additional Topic, thus allowing more photonics-related topics to be covered. Advanced or complicated mathematical derivations are avoided and, instead, the emphasis is placed on concepts and engineering applications. Useful and essential equations in photonics are given with explanations and are used in examples and problems to give the student a sense of what typical values are. Cross referencing in the second edition has been avoided as much as possible, without too much repetition, to allow various sections and chapters to be skipped as desired by the reader. There is greater emphasis on practical or engineering examples; care has been taken to consider various photonics/optoelectronics courses at the undergraduate level across major universities. The second edition is supported by an extensive PowerPoint presentation for instructors who have adopted the book for their course. The PowerPoint slides have all the illustrations in color, and include additional color photos. The basic concepts and equations are also highlighted in additional slides. There are also numerous slides with examples and solved problems. Instructors should visit www.pearsoninternationaleditions.com/kasap to access the PowerPoints. The second edition is also supported by an extensive Solutions Manual for instructors only. This is available from the publisher at www.pearsoninternationaleditions/kasap. The second edition continues to represent a first course in optoelectronic materials and devices suitable for a half- or one-semester course at the undergraduate level either at the thirdor fourth-year level in electrical engineering, engineering physics, and materials science and engineering departments. With its additional topics, it can also be used as an introductory textbook at the graduate level. Normally the students would not have covered Maxwell’s equations. Although Maxwell’s equations are mentioned in the text to alert the student, they are not used in developing the principles. It is assumed that the students would have taken a basic first- or second-year physics course, with modern physics, and would have seen rudimentary concepts in geometrical optics, interference, and diffraction, but not Fresnel’s equations and concepts such as group velocity and group index. Typically an optoelectronics course would be given either after a semiconductor devices course or concurrently with it. Students would have been exposed to elementary quantum mechanics concepts, perhaps in conjunction with a basic semiconductor science course. Most topics are initially introduced through qualitative explanations to allow the concept to be grasped first before any mathematical development. The mathematical level is assumed to include vectors, complex numbers, and partial differentiation but excludes reliance on Fourier transforms. On the one hand, we are required to cover as much as possible and, on the other hand, professional engineering accreditation requires students to solve numerical problems and carry out “design calculations.” In preparing the text, I tried to satisfy engineering degree accreditation requirements in as much breadth as possible. Obviously one cannot solve numerical problems, carry out design calculations, and at the same time derive each equation without expanding the size of the text to an intolerable level. I have missed many topics but I have also covered many, though, undoubtedly, it is my own very biased selection. I would like to thank two very special colleagues, whom I have known for a very long time, for their comments and help: Harry Ruda (University of Toronto) and Raman Kashyap (école Polytechnique de Montréal)—two perfect gentlemen who read some of the manuscript and made valuable criticisms toward this final version. write to me with your comments. Although I may not be able to reply to each individual comment and suggestion, I do read all my email messages and take good note of suggestions and comments. Many instructors did, in fact, write to me on the first edition, pointed out how things could have been done better, and various mistakes one never seems to be able to eliminate totally. I hope that the second edition will at least go far in satisfying some of their criticisms. There is an important old adage that goes something like this (somewhat paraphrased), “a good diagram is worth a thousand words, but a bad diagram takes a thousand words to explain.” I used a software package called Canvas to draw nearly all the line-art in the second edition as clearly as possible, and errors are all mea culpa; feel free to email me the errors you notice in the figures. All third-party artwork and photographs have been used with permission; and I’m grateful to Pearson Education for meticulously obtaining permission from copyright holders. If you like the second edition, and cannot wait for the third, you can always write your comments and recommendations directly to the Sponsoring Editor for Electrical Engineering, Pearson Higher Education, One Lake Street, Upper Saddle River, NJ 07458, USA. This is the best way to have your input heard. Resources for Instructors Instructor’s Solutions Manual. An instructor’s solutions manual was prepared by the author. Presentation Resources. All art from the text is available in PowerPoint slide and JPEG format. These files are available for download from the instructor Resource Center at Kasap. If you are in need of a login and password for this site, please contact your local Pearson Prentice-Hall representative.
S.O.Kasap,是加拿大萨斯喀彻温大学(University of Saskatchewan)电气工程系教授以及加拿大电子材料与器件首席科学家(Canada Research Chair)。他于1976年、1978年和1983年在伦敦大学帝国理工学院(Imperial College of Science。Technology and Medicine,University of London)分别获得学士、硕士和博士学位。他的研究兴趣涵盖了光电子材料与器件的许多方面,如光子晶体光纤布拉格光栅、光通信、医疗成像、半导体器件的电气噪声特性等。S.O.Kasap已在权威国际期刊发表多篇论文。他还是英国电气工程师学会(IEE)、英国物理学会和英国材料学会的会士。目前,他是Journal of Materials Science的副主编。
Chapter 1 Wave Nature of Light
1.1 Light Waves in a Homogeneous Medium 1.2 Refractive Index and Dispersion 1.3 Group Velocity and Group Index 1.4 Magnetic Field, Irradiance, and Poynting Vector 1.5 Snell's Law and Total Internal Reflection (TIR) 1.6 Fresnel's Equations 1.7 Antireflection Coatings and Dielectric Mirrors 1.8 Absorption of Light and Complex Refractive Index 1.9 Temporal and Spatial Coherence 1.10 Superposition and Interference of Waves 1.11 Multiple Interference and Optical Resonators 1.12 Diffraction Principles 1.13 Interferometers 1.14 Thin Film Optics: Multiple Reflections in Thin Films 1.15 Multiple Reflections in Plates and Incoherent Waves 1.16 Scattering of Light 1.17 Photonic Crystals Chapter 2 Dielectric Waveguides and Optical Fibers 2.1 Symmetric Planar Dielectric Slab Waveguide 2.2 Modal and Waveguide Dispersion in Planar 2.3 Step-Index Optical Fiber 2.4 Numerical Aperture 2.5 Dispersion In Single-Mode Fibers 2.6 Dispersion Modified Fibers and Compensation 2.7 Bit Rate, Dispersion, and Electrical and Optical Bandwidth 2.8 The Graded Index (GRIN) Optical Fiber 2.9 Attenuation in Optical Fibers 2.10 Fiber Manufacture 2.11 Wavelength Division Multiplexing: WDM 2.12 Nonlinear Effects in Optical Fibers and DWDM 2.13 Bragg Fibers 2.14 Photonic Crystal Fibers-Holey Fibers 2.15 Fiber Bragg Gratings and Sensors Chapter 3 Semiconductor Science and Light-Emitting Diodes 3.1 Review of Semiconductor Concepts and Energy Bands 3.2 Semiconductor Statistics 3.3 Extrinsic Semiconductors 3.4 Direct and Indirect Bandgap Semiconductors: 3.5 pn Junction Principles 3.6 pn Junction Reverse Current 3.7 pn Junction Dynamic Resistance and Capacitances 3.8 Recombination Lifetime 3.9 pn Junction Band Diagram 3.10 Heterojunctions 3.11 Light-Emitting Diodes: Principles 3.12 Quantum Well High Intensity LEDs 3.13 LED Materials and Structures 3.14 LED Efficiencies and Luminous Flux 3.15 Basic LED Characteristics 3.16 LEDs for Optical Fiber Communications 3.17 Phosphors and White LEDs 3.18 LED Electronics Chapter 4 Stimulated Emission Devices: Optical Amplifiers and Lasers 4.1 Stimulated Emission, Photon Amplification, and Lasers 4.2 Stimulated Emission Rate and Emission Cross-Section 4.3 Erbium-Doped Fiber Amplifiers 4.4 Gas Lasers: The He-Ne Laser 4.5 The Output Spectrum of a Gas Laser 4.6 Laser Oscillations: Threshold Gain Coefficient 4.7 Broadening of the Optical Gain Curve and Linewidth 4.8 Pulsed Lasers: Q-Switching and Mode Locking 4.9 Principle of the Laser Diode 4.10 Heterostructure Laser Diodes 4.11 Quantum Well Devices 4.12 Elementary Laser Diode Characteristics 4.13 Steady State Semiconductor Rate Equations: 4.14 Single Frequency Semiconductor Lasers 4.15 Vertical Cavity Surface Emitting Lasers 4.16 Semiconductor Optical Amplifiers 4.17 Superluminescent and Resonant Cavity Leds: 4.18 Direct Modulation of Laser Diodes 4.19 Holography Chapter 5 Photodetectors and Image Sensors 5.1 Principle of the pn Junction Photodiode 5.2 Shockley-Ramo Theorem and External Photocurrent 5.3 Absorption Coefficient and Photodetector Materials 5.4 Quantum Efficiency and Responsivity 5.5 The pin Photodiode 5.6 Avalanche Photodiode 5.7 Heterojunction Photodiodes 5.8 Schottky Junction Photodetector 5.9 Phototransistors 5.10 Photoconductive Detectors and Photoconductive 5.11 Basic Photodiode Circuits 5.12 Noise in Photodetectors 5.13 Image Sensors 5.14 Photovoltaic Devices: Solar Cells Chapter 6 Polarization and Modulation of Light 6.1 Polarization 6.2 Light Propagation in an Anisotropic Medium: 6.3 Birefringent Optical Devices 6.4 Optical Activity and Circular Birefringence 6.5 Liquid Crystal Displays 6.6 Electro-Optic Effects 6.7 Integrated Optical Modulators 6.8 Acousto-Optic Modulator 6.9 Faraday Rotation and Optical Isolators 6.10 Nonlinear Optics and Second Harmonic Generation 6.11 Jones Vectors ……
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