Advanced Circuits for Emerging Technologies

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Informationen zum Autor Krzysztof (Kris) Iniewski, PhD, manages R&D developments at Redlen Technologies. He is also an executive director at CMOS Emerging Technologies. A former associate professor in the Electrical Engineering and Computer Engineering and Computer Engineering Department at the University of Alberta, Dr. Iniewski's Main research interest is in IC design for medical and networking applications. Klappentext The book will address the-state-of-the-art in integrated circuit design in the context of emerging systems. New exciting opportunities in body area networks, wireless communications, data networking, and optical imaging are discussed. Emerging materials that can take system performance beyond standard CMOS, like Silicon on Insulator (SOI), Silicon Germanium (SiGe), and Indium Phosphide (InP) are explored. Three-dimensional (3-D) CMOS integration and co-integration with sensor technology are described as well. The book is a must for anyone serious about circuit design for future technologies.The book is written by top notch international experts in industry and academia. The intended audience is practicing engineers with integrated circuit background. The book will be also used as a recommended reading and supplementary material in graduate course curriculum. Intended audience is professionals working in the integrated circuit design field. Their job titles might be : design engineer, product manager, marketing manager, design team leader, etc. The book will be also used by graduate students. Many of the chapter authors are University Professors. Zusammenfassung CMOS technology is the dominant technology for fabricating integrated circuits (ICs or chips). It is reliable, manufacturable, low power, low cost, and most importantly, scalable. This authoritative CMOS circuit design book covers advanced circuits for emerging technologies, including digital VLSI, analog VLSI and VSLI memories. Inhaltsverzeichnis Preface xiii Contributors xv Part I Digital Design and Power Management 1 Design in the Energy-Delay Space 3 Massimo Alioto, Elio Consoli, and Gaetano Palumbo 1.1 Introduction 3 1.2 Energy and Delay Modeling 4 1.3 Energy-Delay Space Analysis and Hardware-Intensity 14 1.4 Energy-Efficient Design of Digital Circuits 20 1.5 Design of Energy-Efficient Pipelined Systems 29 1.6 Conclusion 36 References 37 2 Subthreshold Source-Coupled Logic 41 Armin Tajalli and Yusuf Leblebici 2.1 Introduction 41 2.2 Ultralow Power CMOS Logic: Design and Tradeoffs 43 2.3 Subthreshold Source-Coupled Logic 47 2.4 Power-Frequency Scaling 51 2.5 Conclusions 53 References 55 3 Ultralow-Voltage Design of Nanometer CMOS Circuits for Smart Energy-Autonomous Systems 57 David Bol 3.1 Introduction 57 3.2 Impact of Technology Scaling on Subthreshold MOSFET Characteristics 61 3.3 Scaling Trend of the Minimum-Energy Point 63 3.4 Practical Energy of Nanometer ULV Circuits under Robustness and Timing Constraints 69 3.5 Technology/Circuit Methodology and Roadmap for ULV Design in the Nanometer Era 75 3.6 Conclusion 78 References 79 4 Impairment-Aware Analog Circuit Design by Reconfiguring Feedback Systems 85 Ping-Ying Wang 4.1 Introduction 86 4.2 Theorem of Impairment-Aware Analog Design in Feedback Systems 86 4.3 Practical Implementations 89 4.4 Measured Results 96 4.5 Conclusions 99 References 100 5 Rom-Based Logic Design: A Low-Power Design Perspective 103 Bipul C. Paul 5.1 Introduction 103 5.2 RBL Design 105 5.3 RBL Adder 108 5.4 RBL Multiplier 111 5.5 Conclusions 116 References 117 6 Power Management: Enabling Te...

List of contents

Preface xiii
 
Contributors xv
 
PART I DIGITAL DESIGN AND POWER MANAGEMENT
 
1 DESIGN IN THE ENERGY-DELAY SPACE 3
Massimo Alioto, Elio Consoli, and Gaetano Palumbo
 
1.1 Introduction 3
 
1.2 Energy and Delay Modeling 4
 
1.3 Energy-Delay Space Analysis and Hardware-Intensity 14
 
1.4 Energy-Efficient Design of Digital Circuits 20
 
1.5 Design of Energy-Efficient Pipelined Systems 29
 
1.6 Conclusion 36
 
References 37
 
2 SUBTHRESHOLD SOURCE-COUPLED LOGIC 41
Armin Tajalli and Yusuf Leblebici
 
2.1 Introduction 41
 
2.2 Ultralow Power CMOS Logic: Design and Tradeoffs 43
 
2.3 Subthreshold Source-Coupled Logic 47
 
2.4 Power-Frequency Scaling 51
 
2.5 Conclusions 53
 
References 55
 
3 ULTRALOW-VOLTAGE DESIGN OF NANOMETER CMOS CIRCUITS FOR SMART ENERGY-AUTONOMOUS SYSTEMS 57
David Bol
 
3.1 Introduction 57
 
3.2 Impact of Technology Scaling on Subthreshold MOSFET Characteristics 61
 
3.3 Scaling Trend of the Minimum-Energy Point 63
 
3.4 Practical Energy of Nanometer ULV Circuits under Robustness and Timing Constraints 69
 
3.5 Technology/Circuit Methodology and Roadmap for ULV Design in the Nanometer Era 75
 
3.6 Conclusion 78
 
References 79
 
4 IMPAIRMENT-AWARE ANALOG CIRCUIT DESIGN BY RECONFIGURING FEEDBACK SYSTEMS 85
Ping-Ying Wang
 
4.1 Introduction 86
 
4.2 Theorem of Impairment-Aware Analog Design in Feedback Systems 86
 
4.3 Practical Implementations 89
 
4.4 Measured Results 96
 
4.5 Conclusions 99
 
References 100
 
5 ROM-BASED LOGIC DESIGN: A LOW-POWER DESIGN PERSPECTIVE 103
Bipul C. Paul
 
5.1 Introduction 103
 
5.2 RBL Design 105
 
5.3 RBL Adder 108
 
5.4 RBL Multiplier 111
 
5.5 Conclusions 116
 
References 117
 
6 POWER MANAGEMENT: ENABLING TECHNOLOGY 119
Lou Hutter and Felicia James
 
6.1 Macroeconomic Drivers for Power Technologies 119
 
6.2 Market Trends 122
 
6.3 Application Examples 123
 
6.4 Technology Implications and Trends 124
 
6.5 Current Technologies and Capabilities 130
 
6.6 Specific Application Example 140
 
6.7 Emerging Technologies 142
 
6.8 Conclusion 143
 
References 143
 
7 ULTRALOW POWER MANAGEMENT CIRCUIT FOR OPTIMAL ENERGY HARVESTING IN WIRELESS BODY AREA NETWORK 147
Yen Kheng Tan, Yuanjin Zheng, and Huey Chian Foong
 
7.1 Introduction 147
 
7.2 Wireless Body Area Network 148
 
7.3 Optimal Energy Harvesting System 159
 
7.4 Ultralow Power Management Integrated Circuit for Solar Energy Harvesting System 163
 
7.5 Conclusions 171
 
References 171
 
PART II ANALOG AND RF DESIGN
 
8 ANALOG CIRCUIT DESIGN FOR SOI 177
Andrew Marshall
 
8.1 SOI Devices 177
 
8.2 Partially Depleted SOI 178
 
8.3 FDSOI and FinFET 181
 
8.4 Device Considerations (FDSOI AND PDSOI) 181
 
8.5 Analog Circuit Building Blocks 184
 
8.6 Operational Amplifiers 189
 
8.7 Operational Transconductance Amplifier 193
 
8.8 Radio Frequency Low-Noise Amplifier 197
 
8.9 Mixers and Analog Multipliers 197
 
8.10 Analog to Digital and Digital to Analog Converters 201
 
8.11 Summary 204
 
References 204
 

9 FREQUENCY GENERATION AND CONTROL WITH SELF-REFERENCED CMOS OSCILLATORS 207
Michael S. McCorquodale, Nathaniel Gaskin, and Vidyabhusan Gupta
 
9.1 Introduction 207
 
9.2 Self-Referenced CMOS Oscillators 211