000 12754nam a2201333 i 4500
001 5628418
003 IEEE
005 20220712205747.0
006 m o d
007 cr |n|||||||||
008 151221s2010 njua ob 001 eng d
010 _z 2010001881 (print)
020 _a9780470634455
_qebook
020 _z9780470277119
_qhardback
020 _z0470277114
_qhardback
020 _z0470634456
_qelectronic
024 7 _a10.1002/9780470634455
_2doi
035 _a(CaBNVSL)mat05628418
035 _a(IDAMS)0b0000648138cd7d
040 _aCaBNVSL
_beng
_erda
_cCaBNVSL
_dCaBNVSL
050 4 _aTK6564.3
_b.M85 2011eb
082 0 0 _a384.5/3
_222
245 0 0 _aMulti-mode/multi-band RF transceivers for wireless communications :
_badvanced techniques, architectures, and trends /
_cedited by Gernot Hueber, Robert Bogdan Staszewski.
264 1 _a[Hoboken, New Jersey] :
_bWiley,
_cc2011.
264 2 _a[Piscataqay, New Jersey] :
_bIEEE Xplore,
_c[2010]
300 _a1 PDF (xiii, 594 pages) :
_billustrations.
336 _atext
_2rdacontent
337 _aelectronic
_2isbdmedia
338 _aonline resource
_2rdacarrier
504 _aIncludes bibliographical references and index.
505 0 _aContributors -- Preface -- I TRANSCEIVER CONCEPTS AND DESIGN -- 1 Software-Defined Radio Front Ends (Jan Craninckx) -- 1.1 Introduction -- 1.2 System-Level Considerations -- 1.3 Wideband LO Synthesis -- 1.4 Receiver Building Blocks -- 1.5 Transmitter Building Blocks -- 1.6 Calibration Techniques -- 1.7 Full SDR Implementation -- 1.8 Conclusions -- 2 Software-Defined Transceivers (Gio Cafaro and Bob Stengel) -- 2.1 Introduction -- 2.2 Radio Architectures -- 2.3 SDR Building Blocks -- 2.4 Example of an SDR Transceiver -- 3 Adaptive Multi-Mode RF Front-End Circuits (Aleksandar Tasic) -- 3.1 Introduction -- 3.2 Adaptive Multi-Mode Low-Power Wireless RF IC Design -- 3.3 Multi-Mode Receiver Concept -- 3.4 Design of a Multi-Mode Adaptive RF Front End -- 3.5 Experimental Results for the Image-Reject Down-Converter -- 3.6 Conclusions -- 4 Precise Delay Alignment Between Amplitude and Phase/Frequency Modulation Paths in a Digital Polar Transmitter (KhurramWaheed and Robert Bogdan Staszewski) -- 4.1 Introduction -- 4.2 RF Polar Transmitter in Nanoscale CMOS -- 4.3 Amplitude and Phase Modulation -- 4.4 Mechanisms to Achieve Subnanosecond Amplitude and Phase Modulation Path Alignments -- 4.5 Precise Alignment of Multi-Rate Direct and Reference Point Data -- 5 Overview of Front-End RF Passive Integration into SoCs (Hooman Darabi) -- 5.1 Introduction -- 5.2 The Concept of a Receiver Translational Loop -- 5.3 Feedforward Loop Nonideal Effects -- 5.4 Feedforward Receiver Circuit Implementations -- 5.5 Feedforward Receiver Experimental Results -- 5.6 Feedback Notch Filtering for a WCDMA Transmitter -- 5.7 Feedback-Based Transmitter Stability Analysis -- 5.8 Impacts of Nonidealities in Feedback-Based Transmission -- 5.9 Transmitter Building Blocks -- 5.10 Feedback-Based Transmitter Measurement Results -- 5.11 Conclusions and Discussion -- 6 ADCs and DACs for Software-Defined Radio (Michiel Steyaert, Pieter Palmers, and Koen Cornelissens) -- 6.1 Introduction -- 6.2 ADC and DAC Requirements in Wireless Systems.
505 8 _a6.3 Multi-Standard Transceiver Architectures -- 6.4 Evaluating Reconfigurability -- 6.5 ADCs for Software-Defined Radio -- 6.6 DACs for Software-Defined Radio -- 6.7 Conclusions -- II RECEIVER DESIGN -- 7 OFDM Transform-Domain Receivers for Multi-Standard Communications (Sebastian Hoyos) -- 7.1 Introduction -- 7.2 Transform-Domain Receiver Background -- 7.3 Transform-Domain Sampling Receiver -- 7.4 Digital Baseband Design for the TD Receiver -- 7.5 A Comparative Study -- 7.6 Simulations -- 7.7 Gain-Bandwidth Product Requirement for an Op-Amp in a Charge-Sampling Circuit -- 7.8 Sparsity of (GHG)-1 -- 7.9 Applications -- 7.10 Conclusions -- 8 Discrete-Time Processing of RF Signals (RenaldiWinoto and Borivoje Nikolic) -- 8.1 Introduction -- 8.2 Scaling of an MOS Switch -- 8.3 Sampling Mixer -- 8.4 Filter Synthesis -- 8.5 Noise in Switched-Capacitor Filters -- 8.6 Circuit-Design Considerations -- 8.7 Perspective and Outlook -- 9 Oversampled ADC Using VCO-Based Quantizers (MatthewZ. Straayer and MichaelH.Perrott) -- 9.1 Introduction -- 9.2 VCO-Quantizer Background -- 9.3 SNDR Limitations for VCO-Based Quantization -- 9.4 VCO Quantizer -ADC Architecture -- 9.5 Prototype -ADC Example with a VCO Quantizer -- 9.6 Conclusions -- References -- 10 Reduced External Hardware and Reconfigurable RF Receiver Front Ends for Wireless Mobile Terminals (Naveen K. Yanduru) -- 10.1 Introduction -- 10.2 Mobile Terminal Challenges -- 10.3 Research Directions Toward a Multi-Band Receiver -- 10.4 Multi-Mode Receiver Principles and RF System Analysis for a W-CDMA Receiver -- 10.5 W-CDMA, GSM/GPRS/EDGE Receiver Front End Without an Interstage SAW Filter -- 10.6 Highly Integrated GPS Front End for Cellular Applications in 90-nm CMOS -- 10.7 RX Front-End Performance Comparison -- 11 Digitally Enhanced Alternate Path Linearization of RF Receivers (Edward A.Keehr and AliHajimiri) -- 11.1 Introduction -- 11.2 Adaptive Feedforward Error Cancellation -- 11.3 Architectural Concepts -- 11.4 Alternate Feedforward Path Block Design Considerations.
505 8 _a11.5 Experimental Design of an Adaptively Linearized UMTS Receiver -- 11.6 Experimental Results of an Adaptively Linearized UMTS Receiver -- 11.7 Conclusions -- III TRANSMITTER TECHNIQUES -- 12 Linearity and Efficiency Strategies for Next-Generation Wireless Communications (Lawrence Larson,Peter Asbeck, and Donald Kimball) -- 12.1 Introduction -- 12.2 Power Amplifier Function -- 12.3 Power Amplifier Efficiency Enhancement -- 12.4 Techniques for Linearity Enhancement -- 12.5 Conclusions -- 13 CMOS RF Power Amplifiers for Mobile Communications (Patrick Reynaert) -- 13.1 Introduction -- 13.2 Challenges -- 13.3 Low Supply Voltage -- 13.4 Average Efficiency, Dynamic Range, and Linearity -- 13.5 Polar Modulation -- 13.6 Distortion in a Polar-Modulated Power Amplifier -- 13.7 Design and Implementation of a Polar-Modulated Power Amplifier -- 13.8 Conclusions -- 14 Digitally Assisted RF Architectures: Two Illustrative Designs (Joel L. Dawson) -- 14.1 Introduction -- 14.2 Cartesian Feedback: The Analog Problem -- 14.3 Digital Assistance for Cartesian Feedback -- 14.4 Multipliers, Squarers, Mixers, and VGAs: The Analog Problem -- 14.5 Digital Assistance for Analog Multipliers -- 14.6 Summary -- Appendix: Stability Analysis for Cartesian Feedback Systems -- IV DIGITAL SIGNAL PROCESSING FOR RF TRANSCEIVERS -- 15 RF Impairment Compensation for Future Radio Systems (Mikko Valkama) -- 15.1 Introduction and Motivation -- 15.2 Typical RF Impairments -- 15.3 Impairment Mitigation Principles -- 15.4 Case Studies in I/Q Imbalance Compensation -- 15.5 Conclusions -- 16 Techniques for the Analysis of Digital Bang-Bang PLLs (Nicola DaDalt) -- 16.1 Introduction -- 16.2 Digital Bang-Bang PLL Architecture -- 16.3 Analysis of the Nonlinear Dynamics of the BBPLL -- 16.4 Analysis of the BBPLL with Markov Chains -- 16.5 Linearization of the BBPLL -- 16.6 Comparison of Measurements and Models -- 17 Low-Power Spectrum Processors for Cognitive Radios (Joy Laskar andKyutae Lim) -- 17.1 Introduction.
505 8 _a17.2 Paradigm Shift from SDR to CR -- 17.3 Challenge and Trends in RFIC/System -- 17.4 Analog Signal Processing -- 17.5 Spectrum Sensing -- 17.6 Multi-Resolution Spectrum Sensing -- 17.7 MRSS Performance -- 17.8 Conclusions -- References -- Index.
506 1 _aRestricted to subscribers or individual electronic text purchasers.
520 _aState-of-the-art and beyond technologies to be used in future multi-mode wireless communication systemsCurrent and future mobile terminals become increasingly complex because they have to deal with a variety of frequency bands and communication standards. Achieving multiband/multimode functionality (3G and beyond) is especially challenging for the RF-transceiver section.This volume presents cutting-edge physical layer technologies for multi-mode wireless RF transceivers, specifically RF, analog, and mixed-signal and digital circuits and architectures. Providing the most comprehensive treatment of this topic available, it features original contributions from distinguished researchers and professionals from both academia and industry, who anticipate the major trends and needs of future wireless system developments.Divided into four sections, Multi-Mode/Multi-Band RF Transceivers for Wireless Communications covers:. Transceiver concepts and design: software-defined radio front-ends/transceivers, adaptive multi-mode RF front-end circuits, delay alignment between amplitude and phase paths in a digital polar transmitter, and front-end RF passive integration, as well as versatile data converters. Receiver design: OFDM transform-domain receivers for multi-standards, discrete-time processing of RF signals, oversampled ADC using VCO-based quantizers, RF receiver front-ends for mobile terminals, and digitally enhanced alternate path linearization of RF receivers. Transmitter techniques: Linearity and efficiency strategies, CMOS RF power amplifiers for mobiles, and digitally assisted RF architectures. Digital Signal Processing for RF transceivers: RF impairment compensation for future radio systems, techniques for the analysis of digital bang-bang PLLs, and low-power spectrum processors for cognitive radiosThe remarkable insight into the essential transceiver building blocks to be used in future multi-mode wireless communication systems makes this an invaluable resource for engineers and researchers from academia and industry working on circuits and architectures of wireless transceivers, as well as for RF design engineers in semiconductor companies and graduate students taking advanced courses on wireless communication circuits.
530 _aAlso available in print.
538 _aMode of access: World Wide Web
588 _aDescription based on PDF viewed 12/21/2015.
650 0 _aWireless LANs
_xEquipment and supplies
_xDesign and construction.
_927534
650 0 _aCell phones
_xDesign and construction.
_94544
650 0 _aWireless communication systems
_xEquipment and supplies
_xDesign and construction.
_927283
650 0 _aRadio
_xTransmitter-receivers.
_927535
655 0 _aElectronic books.
_93294
695 _aAdaptive equalizers
695 _aBandwidth
695 _aBaseband
695 _aCMOS integrated circuits
695 _aCMOS technology
695 _aCapacitance
695 _aCapacitors
695 _aClocks
695 _aCommunication standards
695 _aConverters
695 _aDelay
695 _aDigital signal processing
695 _aEquations
695 _aFeedforward neural networks
695 _aFrequency modulation
695 _aGSM
695 _aHardware
695 _aImpedance
695 _aIndexes
695 _aInductors
695 _aInterference
695 _aLogic gates
695 _aMixers
695 _aMobile communication
695 _aMultiaccess communication
695 _aNoise
695 _aNonlinear distortion
695 _aOFDM
695 _aOscillators
695 _aPeak to average power ratio
695 _aPerformance evaluation
695 _aPhase locked loops
695 _aPower amplifiers
695 _aPower demand
695 _aPower generation
695 _aPower measurement
695 _aPrinters
695 _aQuantization
695 _aRadiation detectors
695 _aRadio frequency
695 _aRadio transmitters
695 _aReceivers
695 _aRegisters
695 _aResonant frequency
695 _aRoads
695 _aSensors
695 _aSignal processing
695 _aSpread spectrum communication
695 _aStability analysis
695 _aStandards
695 _aSurface acoustic waves
695 _aSwitches
695 _aSynchronization
695 _aSystem-on-a-chip
695 _aTrajectory
695 _aTransceivers
695 _aTransistors
695 _aTransmitters
695 _aTuning
695 _aVoltage-controlled oscillators
695 _aWideband
695 _aWireless communication
700 1 _aStaszewski, Robert Bogdan,
_d1965-
_927536
700 1 _aHueber, Gernot,
_d1972-
_927537
710 2 _aJohn Wiley & Sons,
_epublisher.
_96902
710 2 _aIEEE Xplore (Online service),
_edistributor.
_927538
776 0 8 _iPrint version:
_z9780470277119
856 4 2 _3Abstract with links to resource
_uhttps://ieeexplore.ieee.org/xpl/bkabstractplus.jsp?bkn=5628418
942 _cEBK
999 _c74094
_d74094