텍스트북스 소개

도서정보

교수, 강사 전용

출간문의

커뮤니티

도서정보

HOME > 도서정보 > 분야별도서

분야별도서

분야별도서 > 물리 (Physics)

Fiber Optic Communications

Fundamentals and Applications

원서 판매중 Wiley

  • 지은이

    Shiva Kumar, M. Jamal Deen

  • 발행일

    2014

    페이지

    572

  • ISBN

    9780470518670

    사이즈

    19.3*24.9cm

  • 가격

    58,000원

본 도서는 대학강의용 교재로 개발되어 연습문제 풀이와 해답을 제공하지 않습니다.

구매처 : 구내서점. 대형서점. 인터넷서점

Fiber-optic communication systems have advanced dramatically over the last four decades, since the era of copper cables, resulting in low-cost and high-bandwidth transmission. Fiber optics is now the backbone of the internet and long-distance telecommunication. Without it we would not enjoy the benefits of high-speed internet, or low-rate international telephone calls.


This book introduces the basic concepts of fiber-optic communication in a pedagogical way. The important mathematical results are derived by first principles rather than citing research articles. In addition, physical interpretations and real-world analogies are provided to help students grasp the fundamental concepts.

Key Features:

Lucid explanation of key topics such as fibers, lasers, and photodetectors.
Includes recent developments such as coherent communication and digital signal processing.
Comprehensive treatment of fiber nonlinear transmission.
Worked examples, exercises, and answers.
Accompanying website with PowerPoint slides and numerical experiments in MATLAB.

Intended primarily for senior undergraduates and graduates studying fiber-optic communications, the book is also suitable as a professional resource for researchers working in the field of fiber-optic communications.  

Shiva Kumar , Department of Electrical and Computer Engineering, McMaster University, Canada


M. Jamal Deen , Department of Electrical and Computer Engineering, McMaster University, Canada  

Preface xv

Acknowledgments xvii

 

1 Electromagnetics and Optics 1
1.1 Introduction 1
1.2 Coulomb’s Law and Electric Field Intensity 1
1.3 Ampere’s Law and Magnetic Field Intensity 3
1.4 Faraday’s Law 6
1.5 Maxwell’s Equations 9
1.6 1-Dimensional Wave Equation 12
1.7 Power Flow and Poynting Vector 17
1.8 3-Dimensional Wave Equation 19
1.9 Reflection and Refraction 21
1.10 Phase Velocity and Group Velocity 26
1.11 Polarization of Light 31
Exercises 31
Further Reading 34
References 34

2 Optical Fiber Transmission 35
2.1 Introduction 35
2.2 Fiber Structure 35
2.3 Ray Propagation in Fibers 36
2.4 Modes of a Step-Index Optical Fiber* 44
2.5 Pulse Propagation in Single-Mode Fibers 57
2.6 Comparison between Multi-Mode and Single-Mode Fibers 68
2.7 Single-Mode Fiber Design Considerations 68
2.8 Dispersion-Compensating Fibers (DCFs) 79
2.9 Additional Examples 81
Exercises 89
Further Reading 91
References 91

3 Lasers 93
3.1 Introduction 93
3.2 Basic Concepts 93
3.3 Conditions for Laser Oscillations 101
3.4 Laser Examples 108
3.5 Wave?Particle Duality 108
3.6 Laser Rate Equations 110
3.7 Review of Semiconductor Physics 113
3.8 Semiconductor Laser Diode 124
3.9 Additional Examples 133
Exercises 136
Further Reading 138
References 138

4 Optical Modulators and Modulation Schemes 139
4.1 Introduction 139
4.2 Line Coder 139
4.3 Pulse Shaping 139
4.4 Power Spectral Density 141
4.5 Digital Modulation Schemes 144
4.6 Optical Modulators 149
4.7 Optical Realization of Modulation Schemes 158
4.8 Partial Response Signals? 163
4.9 Multi-Level Signaling? 172
4.10 Additional Examples 182
Exercises 185
Further Reading 186
References 187

5 Optical Receivers 189
5.1 Introduction 189
5.2 Photodetector Performance Characteristics 190
5.3 Common Types of Photodetectors 202
5.4 Direct Detection Receivers 219
5.5 Receiver Noise 224
5.6 Coherent Receivers 227
Exercises 242
References 244

6 Optical Amplifiers 247
6.1 Introduction 247
6.2 Optical Amplifier Model 247
6.3 Amplified Spontaneous Emission in Two-Level Systems 248
6.4 Low-Pass Representation of ASE Noise 249
6.5 System Impact of ASE 251
6.6 Semiconductor Optical Amplifiers 263
6.7 Erbium-Doped Fiber Amplifier 274
6.8 Raman Amplifiers 282
6.9 Additional Examples 288
Exercises 298
Further Reading 300
References 300

7 Transmission System Design 301
7.1 Introduction 301
7.2 Fiber Loss-Induced Limitations 301
7.3 Dispersion-Induced Limitations 313
7.4 ASE-Induced Limitations 315
7.5 Additional Examples 327
Exercises 333
Further Reading 334
References 334

8 Performance Analysis 335
8.1 Introduction 335
8.2 Optimum Binary Receiver for Coherent Systems 335
8.3 Homodyne Receivers 345
8.4 Heterodyne Receivers 350
8.5 Direct Detection 368
8.6 Additional Examples 381
Exercises 387
References 388

9 Channel Multiplexing Techniques 389
9.1 Introduction 389
9.2 Polarization-Division Multiplexing 389
9.3 Wavelength-Division Multiplexing 391
9.4 OFDM 402
9.5 Time-Division Multiplexing 409
9.6 Additional Examples 413
Exercises 415
References 416

10 Nonlinear Effects in Fibers 419
10.1 Introduction 419
10.2 Origin of Linear and Nonlinear Refractive Indices 419
10.3 Fiber Dispersion 426
10.4 Nonlinear Schrodinger Equation 428
10.5 Self-Phase Modulation 430
10.6 Combined Effect of Dispersion and SPM 433
10.7 Interchannel Nonlinear Effects 437
10.8 Intrachannel Nonlinear Impairments 454
10.9 Theory of Intrachannel Nonlinear Effects 457
10.10 Nonlinear Phase Noise 471
10.11 Stimulated Raman Scattering 478
10.11.1 Time Domain Description 481
10.12 Additional Examples 483
Exercises 491
Further Reading 493
References 493

11 Digital Signal Processing 497
11.1 Introduction 497
11.2 Coherent Receiver 497
11.3 Laser Phase Noise 498
11.4 IF Estimation and Compensation 501
11.5 Phase Estimation and Compensation 503
11.6 CD Equalization 506
11.7 Polarization Mode Dispersion Equalization 513
11.8 Digital Back Propagation 516
11.8.1 Multi-Span DBP 521
11.9 Additional Examples 522
Exercises 524
Further Reading 525
References 525

AppendixA 527
Appendix B 533

Index 537  

 

 

연관도서