Advanced Techniques, Architectures, and Trends
Buch, Englisch, 608 Seiten, Format (B × H): 160 mm x 236 mm, Gewicht: 1039 g
ISBN: 978-0-470-27711-9
Verlag: Wiley
- Summarizes cutting-edge physical layer technologies for multi-mode wireless RF transceivers.
- Includes original contributions from distinguished researchers and professionals.
- Covers cutting-edge physical layer technologies for multi-mode wireless RF transceivers.
- Contributors are all leading researchers and professionals in this field.
Autoren/Hrsg.
Fachgebiete
Weitere Infos & Material
Contributors xi
Preface xiii
I Transceiver Concepts and Design 1
1 Software-Defined Radio Front Ends 3
Jan Craninckx
1.1 Introduction 3
1.2 System-Level Considerations 4
1.3 Wideband LO Synthesis 5
1.4 Receiver Building Blocks 12
1.5 Transmitter Building Blocks 23
1.6 Calibration Techniques 25
1.7 Full SDR Implementation 27
1.8 Conclusions 30
References 30
2 Software-Defined Transceivers 33
Gio Cafaro and Bob Stengel
2.1 Introduction 33
2.2 Radio Architectures 34
2.3 SDR Building Blocks 34
2.4 Example of an SDR Transceiver 54
References 60
3 Adaptive Multi-Mode RF Front-End Circuits 65
Aleksandar Tasic
3.1 Introduction 65
3.2 Adaptive Multi-Mode Low-Power Wireless RF IC Design 66
3.3 Multi-Mode Receiver Concept 68
3.4 Design of a Multi-Mode Adaptive RF Front End 70
3.5 Experimental Results for the Image-Reject Down-Converter 76
3.6 Conclusions 80
References 81
4 Precise Delay Alignment Between Amplitude and Phase/ Frequency Modulation Paths in a Digital Polar Transmitter 85
Khurram Waheed and Robert Bogdan Staszewski
4.1 Introduction 85
4.2 RF Polar Transmitter in Nanoscale CMOS 87
4.3 Amplitude and Phase Modulation 90
4.4 Mechanisms to Achieve Subnanosecond Amplitude and Phase Modulation Path Alignments 96
4.5 Precise Alignment of Multi-Rate Direct and Reference Point Data 101
References 109
5 Overview of Front-End RF Passive Integration into SoCs 113
Hooman Darabi
5.1 Introduction 113
5.2 The Concept of a Receiver Translational Loop 119
5.3 Feedforward Loop Nonideal Effects 122
5.4 Feedforward Receiver Circuit Implementations 125
5.5 Feedforward Receiver Experimental Results 129
5.6 Feedback Notch Filtering for a WCDMA Transmitter 133
5.7 Feedback-Based Transmitter Stability Analysis 138
5.8 Impacts of Nonidealities in Feedback-Based Transmission 141
5.9 Transmitter Building Blocks 148
5.10 Feedback-Based Transmitter Measurement Results 150
5.11 Conclusions and Discussion 153
Appendix 155
References 156
6 ADCs and DACs for Software-Defined Radio 159
Michiel Steyaert, Pieter Palmers, and Koen Cornelissens
6.1 Introduction 159
6.2 ADC and DAC Requirements in Wireless Systems 160
6.3 Multi-Standard Transceiver Architectures 162
6.4 Evaluating Reconfigurability 165
6.5 ADCs for Software-Defined Radio 166
6.6 DACs for Software-Defined Radio 172
6.7 Conclusions 184
References 184
II Receiver Design 187
7 OFDM Transform-Domain Receivers for Multi-Standard Communications 189
Sebastian Hoyos
7.1 Introduction 189
7.2 Transform-Domain Receiver Background 190
7.3 Transform-Domain Sampling Receiver 191
7.4 Digital Baseband Design for the TD Receiver 195
7.5 A Comparative Study 204
7.6 Simulations 208
7.7 Gain–Bandwidth Product Requirement for an Op-Amp in a Charge-Sampling Circuit 211
7.8 Sparsity of (GHG)-1 213
7.9 Applications 214
7.10 Conclusions 215
References 216
8 Discrete-Time Processing of RF Signals 219
Renaldi Winoto and Borivoje Nikolic
8.1 Introduction 219
8.2 Scaling of an MOS Switch 221
8.3 Sampling Mixer 223
8.4 Filter Synthesis 226
8.5 Noise in Switched-Capacitor Filters 234
8.6 Circuit-Design Considerations 237
8.7 Perspective and Outlook 242
References 244
9 Oversampled ADC Using VCO-Based Quantizers 247
Matthew Z. Straayer and Michael H. Perrott
9.1 Introduction 247
9.2 VCO-Quantizer Background 248
9.3 SNDR Limitations for VCO-Based Quantization 252
9.4 VC
