Design of integrated circuits for optical communications

The only book on integrated circuits for optical communications that fully covers High-Speed IOs, PLLs, CDRs, and transceiver design including optical communication The increasing demand for high-speed transport of data has revitalized optical communications, leading to extensive work on high-speed device and circuit design. With the proliferation of the Internet and the rise in the speed of microprocessors and memories, the transport of data continues to be the bottleneck, motivating work on faster communication channels. Design of Integrated Circuits for Optical Communications, Second Edition deals with the design of high-speed integrated circuits for optical communication transceivers. Building upon a detailed understanding of optical devices, the book describes the analysis and design of critical building blocks, such as transimpedance and limiting amplifiers, laser drivers, phase-locked loops, oscillators, clock and data recovery circuits, and multiplexers. The Second Edition of this bestselling textbook has been fully updated with: A tutorial treatment of broadband circuits for both students and engineers New and unique information dealing with clock and data recovery circuits and multiplexers A chapter dedicated to burst-mode optical communications A detailed study of new circuit developments for optical transceivers An examination of recent implementations in CMOS technology This text is ideal for senior graduate students and engineers involved in high-speed circuit design for optical communications, as well as the more general field of wireline communications.

Preface to First Edition xiii Preface xv About the Author xvii 1 Introduction to Optical Communications 1 1.1 Brief History 1 1.2 Generic Optical System 2 1.3 Design Challenges 5 1.4 State of the Art 6 2 Basic Concepts 8 2.1 Properties of Random Binary Data 8 2.2 Generation of Random Data 12 2.3 Data Formats 14 2.4 Effect of Bandwidth Limitation on Random Data 16 2.5 Effect of Noise on Random Data 21 2.6 Phase Noise and Jitter 24 2.7 Transmission Lines 30 3 Optical Devices 36 3.1 Laser Diodes 36 3.2 Optical Fibers 46 3.3 Photodiodes 55 3.4 Optical Systems 58 4 Transimpedance Amplifiers 62 4.1 General Considerations 62 4.2 Open-Loop TIAs 73 4.3 Feedback TIAs 87 4.4 Supply Rejection 97 4.5 Differential TIAs 100 4.6 High-Performance Techniques 103 4.7 Automatic Gain Control 114 4.8 Case Studies 118 4.9 New Developments in TIA Design 122 5 Limiting Amplifiers and Output Buffers 130 5.1 General Considerations 130 5.2 Broadband Techniques 138 5.3 Output Buffers 149 5.4 Distributed Amplification 159 5.5 Other Broadband Techniques 171 6 Oscillator Fundamentals 185 6.1 General Considerations 185 6.2 Ring Oscillators 187 6.3 LC Oscillators 198 6.4 Voltage-Controlled Oscillators 211 6.5 Mathematical Model of VCOs 227 7 LC Oscillators 233 7.1 Monolithic Inductors 233 7.2 Monolithic Varactors 246 7.3 Basic LC Oscillators 248 7.4 Quadrature Oscillators 255 7.5 Distributed Oscillators 261 8 Phase-Locked Loops 264 8.1 Simple PLL 264 8.2 Charge-Pump PLLs 280 8.3 Nonideal Effects in PLLs 293 8.4 Delay-Locked Loops 300 8.5 Applications 302 9 Clock and Data Recovery 308 9.1 General Considerations 308 9.2 Phase Detectors for Random Data 320 9.3 Frequency Detectors for Random Data 333 9.4 CDR Architectures 338 9.5 Jitter in CDR Circuits 344 10 Multiplexers and Laser Drivers 356 10.1 Multiplexers 356 10.2 Frequency Dividers 364 10.3 Laser and Modulator Drivers 374 10.4 Design Principles 378 10.5 New Developments in Laser Driver Design 385 11 Burst-Mode Circuits 393 11.1 Passive Optical Networks 393 11.2 Burst-Mode TIAs 395 11.3 Burst-Mode CDR Circuits 404 11.4 Alternative BM CDR Architectures 413 Index 417