RF and Digital Signal Processing for Software-Defined Radio (eBook)
400 Seiten
Elsevier Science (Verlag)
978-0-08-094173-8 (ISBN)
Software-defined radio (SDR) technology is a configurable, low cost, and power efficient solution for multimode and multistandard wireless designs. This book describes software-defined radio concepts and design principles from the perspective of RF and digital signal processing as performed within this system. After an introductory overview of essential SDR concepts, this book examines signal modulation techniques, RF and digital system analysis and requirements, Nyquist and oversampled data conversion techniques, and multirate digital signal processing..
KEY TOPICS
•Modulation techniques
Master analog and digital modulation schemes
•RF system-design parameters
Examine noise and link budget analysis and Non-linear signal analysis and design methodology
•Essentials of baseband and bandpass sampling and gain control
IF sampling architecture compared to traditional quadrature sampling, Nyquist zones, automatic gain control, and filtering
•Nyquist sampling converter architectures
Analysis and design of various Nyquist data converters
•Oversampled data converter architectures
Analysis and design of continuous-time and discrete-time Delta-Sigma converters
•Multirate signal processing
Gain knowledge of interpolation, decimation, and fractional data rate conversion
*Offers readers a powerful set of analytical and design tools
*Details real world designs
*Comprehensive coverage makes this a must have in the RF/Wireless industry
Tony J. Rouphael has worked on all aspects of wireless communications ranging from antenna and RF to digital signal processing. At Philips, Siemens, Northrop Grumman, RF Micro Devices, and others, he has developed products in TDMA IS-136, CDMA2000, GSM, WCDMA, UWB, 802.11, and software defined radio for JTRS applications. He holds 48 US patents, published over 20 journal articles in signal processing and communications, and published a book entitled RF and Signal Processing for Software Defined Radio with Elsevier-Newnes.
Understand the RF and Digital Signal Processing Principles Driving Software-defined Radios!Software-defined radio (SDR) technology is a configurable, low cost, and power efficient solution for multimode and multistandard wireless designs. This book describes software-defined radio concepts and design principles from the perspective of RF and digital signal processing as performed within this system. After an introductory overview of essential SDR concepts, this book examines signal modulation techniques, RF and digital system analysis and requirements, Nyquist and oversampled data conversion techniques, and multirate digital signal processing.. KEY TOPICS*Modulation techniquesMaster analog and digital modulation schemes*RF system-design parametersExamine noise and link budget analysis and Non-linear signal analysis and design methodology*Essentials of baseband and bandpass sampling and gain controlIF sampling architecture compared to traditional quadrature sampling, Nyquist zones, automatic gain control, and filtering*Nyquist sampling converter architecturesAnalysis and design of various Nyquist data converters*Oversampled data converter architecturesAnalysis and design of continuous-time and discrete-time Delta-Sigma converters*Multirate signal processing Gain knowledge of interpolation, decimation, and fractional data rate conversion*Offers readers a powerful set of analytical and design tools*Details real world designs*Comprehensive coverage makes this a must have in the RF/Wireless industry
Front Cover 1
RF and Digital Signal Processing for Software-Defined Radio: A Multi-Standard Multi-Mode Approach 4
Copyright Page 5
Contents 8
Acknowledgments 12
Chapter 1: Introduction 14
1.1 The Need for Software-Defined Radio 14
1.2 The Software-Defined Radio Concept 15
1.3 Software Requirements and Reconfigurability 17
1.4 Aim and Organization of the Book 17
References 19
Chapter 2: Common Analog Modulation and Pulse-Shaping Methods 20
2.1 Amplitude Modulation 21
2.2 Frequency and Phase Modulation 26
2.3 Common Pulse-Shaping Functions 31
References 37
Chapter 3: Common Digital Modulation Methods 38
3.1 Channel Capacity Interpreted 39
3.2 PSK Modulation 43
3.3 FSK Modulation 56
3.4 Continuous Phase Modulation (CPM) 69
3.5 Gaussian MSK (GMSK) 69
3.6 On-Off Keying (OOK) 72
3.7 Quadrature Amplitude Modulation (QAM) 74
3.8 Orthogonal Frequency Division Multiplexing (OFDM) 78
3.9 Spread Spectrum Modulation 84
3.10 Appendix 89
References 96
Chapter 4: High-Level Requirements and Link Budget Analysis 100
4.1 High-Level Requirements 101
4.2 Link Budget Analysis 113
4.3 Cascaded Noise Figure Analysis 130
References 135
Chapter 5: Memoryless Nonlinearity and Distortion 136
5.1: 1-dB Compression Point Due to Memoryless Nonlinearities 137
5.2: Signal Desensitization and Blocking 141
5.3: Intermodulation Distortion 142
5.4: Cascaded Input-Referred Intercept Points 153
5.5: Cross Modulation Distortion 155
5.6: Harmonics 162
5.7: Phase Noise and Reciprocal Mixing 165
5.8: Spurious Signals 167
5.9: Appendix 168
References 173
Chapter 6: Transceiver System Analysis and Design Parameters 174
6.1 Receiver Selectivity 174
6.2 Receiver Dynamic Range 178
6.3 AM/AM and AM/PM 180
6.4 Frequency Bands, Accuracy and Tuning 185
6.5 Modulation Accuracy: EVM and Waveform Quality Factor 188
6.6 Adjacent Channel Leakage Ratio (ACLR) 207
6.7 Transmitter Broadband Noise 209
References 211
Chapter 7: Uniform Sampling of Signals and Automatic Gain Control 212
7.1 Sampling of Lowpass Signals 212
7.2 Sampling of Bandpass Signals 220
7.3 The AGC Algorithm 229
7.4 Appendix 246
References 247
Chapter 8: Nyquist-Rate Data Conversion 248
8.1 Nyquist Converters 248
8.2 Overview of Nyquist Sampling Converter Architectures 279
8.3 Appendix 288
References 290
Chapter 9: & #916
9.1 The Concept of & #916
9.2 Comparison between Continuous-Time and Discrete-Time & #916
9.3 SQNR Performance of & #916
9.4 Bandpass & #916
9.5 Common Architectures of & #916
9.6 Further Nonidealities in & #916
References 330
Chapter 10: Multirate Digital Signal Processing 332
10.1 Basics of Sample Rate Conversion 332
10.2 Filter Design and Implementation 353
10.3 Arbitrary Sampling Rate Conversion 377
References 388
Index 390
A 390
B 390
C 391
D 391
F 392
G 392
H 392
I 392
J 393
L 393
M 393
N 394
O 394
P 394
Q 395
R 395
S 395
T 396
U 396
V 396
W 396
Erscheint lt. Verlag | 7.3.2009 |
---|---|
Sprache | englisch |
Themenwelt | Mathematik / Informatik ► Informatik |
Mathematik / Informatik ► Mathematik ► Computerprogramme / Computeralgebra | |
Technik ► Elektrotechnik / Energietechnik | |
Technik ► Nachrichtentechnik | |
ISBN-10 | 0-08-094173-7 / 0080941737 |
ISBN-13 | 978-0-08-094173-8 / 9780080941738 |
Haben Sie eine Frage zum Produkt? |
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