Modern transceiver systems require diversified design aspects as various radio and sensor applications have emerged. Choosing the right architecture and understanding interference and linearity issues are important for multi-standard cellular transceivers and software-defined radios. A millimeter-wave complementary metal–oxide–semiconductor (CMOS) transceiver design for multi-Gb/s data transmission is another challenging area. Energy-efficient short-range radios for body area networks and sensor networks have recently received great attention. To meet different design requirements, gaining good system perspectives is important.
Wireless Transceiver Circuits: System Perspectives and Design Aspects
offers an in-depth look at integrated circuit (IC) design for modern transceiver circuits and wireless systems. Ranging in scope from system perspectives to practical circuit design for emerging wireless applications, this cutting-edge book:
- Provides system design considerations in modern transceiver design
- Covers both systems and circuits for the millimeter-wave transceiver design
- Introduces four energy-efficient short-range radios for biomedical and wireless connectivity applications
- Emphasizes key building blocks in modern transceivers and transmitters, including frequency synthesizers and digital-intensive phase modulators
Featuring contributions from renowned international experts in industry and academia, Wireless Transceiver Circuits: System Perspectives and Design Aspects makes an ideal reference for engineers and researchers in the area of wireless systems and circuits.
Featuring contributions from renowned experts, this book offers an in-depth look at integrated circuit design for modern transceiver circuits and wireless systems. Ranging in scope from system perspectives to practical circuit design for emerging wireless applications, this cutting-edge reference provides system design considerations in modern transceiver design, covers both systems and circuits for the millimeter-wave transceiver design, introduces four energy-efficient short-range radios for biomedical and wireless connectivity applications, and emphasizes key building blocks in modern transceivers and transmitters, including frequency synthesizers and digital-intensive phase modulators.
Arvustused
"This book is great for academic professionals and researchers working in multiple areas of wireless transceivers, since the coverage is comprehensive." Chih-Ming Hung, MediaTek Inc., Hsinchu, Taiwan
| Preface |
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| Editors |
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xix | |
| Contributors |
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SECTION I System Design Perspectives |
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Chapter 1 Analysis, Optimization, and Design of Transceivers with Passive Mixers |
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3 | (28) |
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Chapter 2 Receiver IP2 Variability |
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31 | (30) |
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Chapter 3 Mitigation of Performance Degradation in Radio Receiver Front Ends from Out-of-Band Interference |
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61 | (34) |
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Chapter 4 Interference Filtering with On-Chip Frequency-Translated Filters in Wireless Receivers |
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95 | (22) |
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Chapter 5 Analog Signal Processing for Reconfigurable Receiver Front Ends |
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117 | (30) |
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Chapter 6 Design Considerations for Direct Delta-Sigma Receivers |
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147 | (22) |
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SECTION II Millimeter-Wave Transceivers |
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Chapter 7 60 GHz CMOS Transceiver Chipset for Mobile Devices |
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169 | (20) |
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Chapter 8 Ultrahigh-Speed Wireless Communication with Short-Millimeter-Wave CMOS Circuits |
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189 | (28) |
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Chapter 9 Photonics-Enabled Millimeter-Wave Wireless Systems |
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217 | (28) |
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Chapter 10 CMOS Millimeter-Wave PA Design |
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245 | (36) |
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Chapter 11 Millimeter-Wave Frequency Multiplier with Performance Enhancement |
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281 | (24) |
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SECTION III Biomedical and Short-Range Radios |
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Chapter 12 CMOS UW3 Transceivers for Short-Range Microwave Medical Imaging |
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305 | (30) |
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Chapter 13 Ultralow-Power RF Systems and Building Blocks |
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335 | (36) |
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Chapter 14 Energy-Efficient High Data Rate Transmitter for Biomedical Applications |
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371 | (32) |
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Chapter 15 Design and Implementation of Ultralow-Power ZigBee/WPAN Receiver |
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403 | (24) |
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SECTION IV Modulators and Synthesizers |
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Chapter 16 All-Digital Phase-Locked Loops for Linear Wideband Phase Modulation |
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427 | (18) |
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Chapter 17 Hybrid Phase Modulators with Enhanced Linearity |
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445 | (22) |
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Chapter 18 Low-Noise PLL-Based Frequency Synthesizer |
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467 | (24) |
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Chapter 19 Low-Phase Noise Quadrature Frequency Synthesizer for 60 GHz Radios |
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491 | (24) |
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Chapter 20 Digitally Controlled Oscillators for Wireless Applications |
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515 | (30) |
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| Index |
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545 | |
Woogeun Rhee holds a B.S. from Seoul National University, South Korea; M.S. from the University of California, Los Angeles, USA; and Ph.D. from the University of Illinois, Urbana-Champaign, USA. Previously, Dr. Rhee was with Conexant Systems, Newport Beach, California, USA, and the IBM Thomas J. Watson Research Center, Yorktown Heights, New York, USA. In August 2006, he joined the Institute of Microelectronics at Tsinghua University, Beijing, China. He holds 19 U.S. patents, has edited numerous scientific journals, and is a member of the Technical Program Committee for the IEEE ISSCC and the IEEE A-SSCC.
