Multi-mode/multi-band RF transceivers for wireless communications : advanced techniques, architectures, and trends

Multi-mode/multi-band RF transceivers for wireless communications advanced techniques, architectures, and trends

State-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...

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Detalles Bibliográficos
Otros Autores: Hueber, Gernot, 1972- (-), Staszewski, Robert Bogdan, 1965-
Formato: Libro electrónico
Idioma:Inglés
Publicado: New York : Wiley c2011.
Edición:1st edition
Materias:
Radio > Transmitter-receivers.
Wireless communication systems > Equipment and supplies > Design and construction.
Cell phones > Design and construction.
Wireless LANs > Equipment and supplies > Design and construction.
Ver en Biblioteca Universitat Ramon Llull:https://discovery.url.edu/permalink/34CSUC_URL/1im36ta/alma991009628158506719
Tabla de Contenidos:
  • Contributors
  • 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.
  • 6.3 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.
  • 11.5 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.
  • 17.2 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.

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