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The Resource RF analog impairments modeling for communication systems simulation : application to OFDM-based transceivers, Lydi Smaini

RF analog impairments modeling for communication systems simulation : application to OFDM-based transceivers, Lydi Smaini

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The item RF analog impairments modeling for communication systems simulation : application to OFDM-based transceivers, Lydi Smaini represents a specific, individual, material embodiment of a distinct intellectual or artistic creation found in University of Missouri Libraries.
This item is available to borrow from 2 library branches.

Creator

Smaini, Lydi, 1974-

Summary

"Logically ordered to follow the order of the blocks encountered along a receiver or a transmitter path in a communication platform, this book provides an introduction to system performance metrics, followed by topics on RF/Analog modeling, and simulation examples to support the modeling theory. With an emphasis on practical ways to apply the ideas presented, this book provides a comprehensive approach to unifying theory and practice in RF/Analog system modeling. Readers will be provided with practical RF/Analog system modeling knowledge and examples directly applicable to their on-going transceiver studies and simulations"--
"Covers the design aspects of the front end of transceivers, both receivers and transmitters"--

Language: eng

Work

Publication

Chichester, West Sussex, United Kingdom, Wiley, 2012

Extent: 1 online resource

Note: Machine generated contents note: 1 Chapter 1: Introduction to Communication System- On-Chip, RF analog front-end, OFDM modulation, and performance metrics 1.1 Communication System-on-Chip 1.1.1 Introduction 1.1.2 CMOS technology 1.1.3 Coexistence Issues 1.2 RF Analog Front-End Overview 1.2.1 Introduction 1.2.2 Super-heterodyne transceiver 1.2.3 Homodyne transceiver 1.2.4 Low-IF transceiver 1.2.5 Analog baseband Filter order vs. ADC dynamic range 1.2.6 Digital compensation of RF Analog Front-End imperfections 1.3 OFDM modulation 1.3.1 OFDM as a Multicarrier modulation 1.3.2 Fourier Transform and Orthogonal Subcarriers 1.3.3 Channel estimation and equalization in frequency domain 1.3.4 Pilot-tones 1.3.5 Guard interval 1.3.6 Windowed OFDM 1.3.7 Adaptive Transmission 1.3.8 OFDMA for Multiple Access 1.3.9 Scalable OFDMA 1.3.10 OFDM digital baseband architecture 1.3.11 OFDM-based standards 1.4 SNR, EVM, and Eb/N0 definitions and relationship 1.4.1 Bit error rate 1.4.2 SNR vs. EVM 1.4.3 SNR vs. Eb/N0 1.4.4 Complex baseband representation 2 Chapter 2: RF Analog impairments description and modeling 2.1 Introduction 2.2 Thermal Noise 2.2.1 Additive White Gaussian Noise 2.2.2 Noise Figure and Sensitivity 2.2.3 Cascaded noise voltage in IC design 2.2.4 AWGN in simulations 2.2.5 Flicker Noise and AWGN modeling 2.3 Oscillator Phase Noise 2.3.1 Description and Impact on the system 2.3.2 Phase Noise Modeling in Frequency Domain 2.3.3 Simulation in Temporal Domain 2.3.4 SNR limitation due to the phase noise 2.3.5 Impact of phase noise in OFDM 2.4 Sampling jitter 2.4.1 Jitter definitions 2.4.2 Sampling jitter and phase noise relationship 2.4.3 SNR limitation due to sampling jitter 2.4.4 Impact of sampling jitter in OFDM 2.4.5 Sampling jitter modeling 2.5 Carrier Frequency Offset 2.5.1 Description 2.5.2 Impact of Carrier Frequency Offset in OFDM 2.6 Sampling Frequency Offset 2.6.1 Description 2.6.2 Impact of Sampling Frequency Offset in OFDM 2.7 I & Q mismatch 2.7.1 Description 2.7.2 IQ mismatch modeling 2.7.3 SNR limitation due to IQ mismatch 2.7.4 Impact of IQ mismatch in OFDM 2.8 DAC/ADC quantization noise and clipping 2.8.1 SNR limitation due to the quantization noise and clipping level 2.8.2 Impact of converter clipping level in OFDM 2.8.3 DAC and ADC dynamic range in OFDM 2.8.4 DAC and ADC modeling 2.9 IP2 and IP3: 2nd and 3rd Order non-linearities 2.9.1 Harmonics (Single-tone test) 2.9.2 Intermodulation Distortion (Two-tone test) 2.9.3 Receiver performance degradation due to the non-linearities 3 Chapter 3: Simulation of the RF Analog impairments impact on real OFDM-based transceivers performance 3.1 Introduction 3.2 WLAN and mobile WIMAX PHY overview 3.2.1 WLAN: Standard IEEE 802.11a/g 3.2.2 Mobile WiMAX: Standard IEEE 802.16e 3.3 Simulation bench overview 3.3.1 WiFi and WiMAX OFDM transceiver modeling 3.3.2 EVM estimation as performance metric 3.3.3 EVM vs. SNR simulations in AWGN channel 3.4 WiFi OFDM and mobile WiMAX signals PAPR 3.5 Transmitter impairments simulation 3.5.1 Introduction 3.5.2 DAC clipping and resolution 3.5.3 I & Q mismatch 3.5.4 RF oscillator phase noise 3.5.5 Power amplifier distortion 3.5.6 Transmitter complete simulation 3.6 Receiver impairments simulation 3.6.1 Introduction 3.6.2 Carrier Frequency Offset 3.6.3 Sampling Frequency Offset 3.6.4 Linearity: IIP2 and IIP3 3.6.5 I & Q mismatch 3.6.6 RF oscillator phase noise and reciprocal mixing 3.6.7 Sampling jitter 3.6.8 ADC clipping and resolution 3.6.9 Receiver complete simulation 3.7 Adaptive modulation illustration 3.8 Summary 4 Chapter 4: Digital Compensation of RF analog Impairments 4.1 Introduction 4.2 Carrier Frequency Offset Estimation and Correction 4.2.1 CFO estimation principle 4.2.2 CFO estimation in time domain 4.2.3 CFO estimation in frequency domain 4.2.4 CFO correction 4.3 Sampling Frequency Offset Estimation and Correction 4.3.1 SFO estimation principle 4.3.2 SFO estimation 4.3.3 SFO correction 4.3.4 Joint SFO and CFO estimation 4.4 IQ mismatch estimation and correction 4.4.1 Principle 4.4.2 Effect of the channel 4.4.3 Simulation results 4.5 Power Amplifier Linearization 4.5.1 Digital Predistortion Principle 4.5.2 Memory polynomial predistortion 4.5.3 Polynomial coefficients computation 4.5.4 Simulation results 4.6 Summary

Contents

CMOS Technology
2.4.5.
Sampling Jitter Modeling
2.5.
Carrier Frequency Offset
2.5.1.
Description
2.5.2.
Impact of CFO in OFDM
2.6.
Sampling Frequency Offset
1.1.3.
2.6.1.
Description
2.6.2.
Impact of SFO in OFDM
2.7.
I and Q Mismatch
2.7.1.
Description
2.7.2.
IQ Mismatch Modeling
Coexistence Issues
2.7.3.
SNR Limitation due to IQ Mismatch
2.7.4.
Impact of IQ Mismatch in OFDM
2.8.
DAC/ADC Quantization Noise and Clipping
2.8.1.
SNR Limitation due to the Quantization Noise and Clipping Level
2.8.2.
Impact of Converter Clipping Level in OFDM
1.2.
2.8.3.
DAC and ADC Dynamic Range in OFDM
2.8.4.
DAC and ADC Modeling
2.9.
IP2 and IP3: Second- and Third-Order Nonlinearities
2.9.1.
Harmonics (Single-Tone Test)
2.9.2.
Intermodulation Distortion (Two-Tone Test)
RF AFE Overview
2.9.3.
Receiver Performance Degradation due to the Non-linearities
2.9.4.
Impact of Third-Order Nonlinearity in OFDM
2.9.5.
Simulation in Complex Baseband
2.10.
Power Amplifier Distortion
2.10.1.
PA Modeling
1.2.1.
2.10.2.
Impact of PA Distortions in OFDM
References
3.
Simulation of the RF Analog Impairments Impact on Real OFDM-Based Transceiver Performance
3.1.
Introduction
3.2.
WLAN and Mobile WiMAX PHY Overview
3.2.1.
Introduction
WLAN: Standard IEEE 802.11a/g
3.2.2.
Mobile WiMAX: Standard IEEE 802.16e
3.3.
Simulation Bench Overview
3.3.1.
WiFi and WiMAX OFDM Transceiver Modeling
3.3.2.
EVM Estimation as Performance Metric
3.3.3.
1.2.2.
EVM versus SNR Simulations in AWGN Channel
3.4.
WiFi OFDM and Mobile WiMAX Signals PAPR
3.5.
Transmitter Impairments Simulation
3.5.1.
Introduction
3.5.2.
DAC Clipping and Resolution
3.5.3.
Superheterodyne Transceiver
I and Q Mismatch
3.5.4.
RF Oscillator Phase Noise
3.5.5.
Power Amplifier Distortion
3.5.6.
Transmitter Complete Simulation
3.6.
Receiver Impairments Simulation
3.6.1.
1.2.3.
Introduction
3.6.2.
Carrier Frequency Offset
3.6.3.
Sampling Frequency Offset
3.6.4.
Linearity: IIP2 and IIP3
3.6.5.
I and Q Mismatch
3.6.6.
Machine generated contents note:
Homodyne Transceiver
RF Oscillator Phase Noise and Reciprocal Mixing
3.6.7.
Sampling Jitter
3.6.8.
ADC Clipping and Resolution
3.6.9.
Receiver Complete Simulation
3.7.
Adaptive Modulation Illustration
3.8.
1.2.4.
Summary
References
4.
Digital Compensation of RF Analog Impairments
4.1.
Introduction
4.2.
CFO Estimation and Correction
4.2.1.
CFO Estimation Principle
Low-IF Transceiver
4.2.2.
CFO Estimation in the Time Domain
4.2.3.
CFO Estimation in the Frequency Domain
4.2.4.
CFO Correction
4.3.
SFO Estimation and Correction
4.3.1.
SFO Estimation Principle
1.2.5.
4.3.2.
SFO Estimation
4.3.3.
SFO Correction
4.3.4.
Joint SFO and CFO Estimation
4.4.
IQ Mismatch Estimation and Correction
4.4.1.
Principle
Analog Baseband Filter Order versus ADC Dynamic Range
4.4.2.
Effect of the Channel
4.4.3.
Simulation Results
4.5.
Power Amplifier Linearization
4.5.1.
Digital Predistortion Principle
4.5.2.
Memory Polynomial Predistortion
1.2.6.
4.5.3.
Polynomial Coefficients Computation
4.5.4.
Simulation Results
4.6.
Summary
References
Digital Compensation of RF Analog Front-End Imperfections
1.3.
OFDM Modulation
1.3.1.
1.
OFDM as a Multicarrier Modulation
1.3.2.
Fourier Transform and Orthogonal Subcarriers
1.3.3.
Channel Estimation and Equalization in Frequency Domain
1.3.4.
Pilot-Tones
1.3.5.
Guard Interval
1.3.6.
Introduction to Communication System-on-Chip, RF Analog Front-End, OFDM Modulation, and Performance Metrics
Windowed OFDM
1.3.7.
Adaptive Transmission
1.3.8.
OFDMA for Multiple Access
1.3.9.
Scalable OFDMA
1.3.10.
OFDM DBB Architecture
1.3.11.
1.1.
OFDM-Based Standards
1.4.
SNR, EVM, and Eb/No Definitions and Relationship
1.4.1.
Bit Error Rate
1.4.2.
SNR versus EVM
1.4.3.
SNR versus Eb/No
1.4.4.
Communication System-on-Chip
Complex Baseband Representation
References
2.
RF Analog Impairments Description and Modeling
2.1.
Introduction
2.2.
Thermal Noise
2.2.1.
Additive White Gaussian Noise
1.1.1.
2.2.2.
Noise Figure and Sensitivity
2.2.3.
Cascaded Noise Voltage in IC Design
2.2.4.
AWGN in Simulations
2.2.5.
Flicker Noise and AWGN Modeling
2.3.
Oscillator Phase Noise
Introduction
2.3.1.
Description and Impact on the System
2.3.2.
Phase Noise Modeling in the Frequency Domain
2.3.3.
Simulation in Temporal Domain
2.3.4.
SNR Limitation due to the Phase Noise
2.3.5.
Impact of Phase Noise in OFDM
1.1.2.
2.4.
Sampling Jitter
2.4.1.
Jitter Definitions
2.4.2.
Sampling Jitter and Phase Noise Relationship
2.4.3.
SNR Limitation due to Sampling Jitter
2.4.4.
Impact of Sampling Jitter in OFDM

Isbn: 9781283645157

Instance

Label: RF analog impairments modeling for communication systems simulation : application to OFDM-based transceivers

Title: RF analog impairments modeling for communication systems simulation

Title remainder: application to OFDM-based transceivers

Statement of responsibility: Lydi Smaini

Creator

Smaini, Lydi, 1974-

Subject

Genre

Electronic books

Language: eng

Summary

"Logically ordered to follow the order of the blocks encountered along a receiver or a transmitter path in a communication platform, this book provides an introduction to system performance metrics, followed by topics on RF/Analog modeling, and simulation examples to support the modeling theory. With an emphasis on practical ways to apply the ideas presented, this book provides a comprehensive approach to unifying theory and practice in RF/Analog system modeling. Readers will be provided with practical RF/Analog system modeling knowledge and examples directly applicable to their on-going transceiver studies and simulations"--
"Covers the design aspects of the front end of transceivers, both receivers and transmitters"--

Member of

Assigning source

Provided by publisher
Provided by publisher

Cataloging source: DLC

http://library.link/vocab/creatorDate: 1974-

http://library.link/vocab/creatorName: Smaini, Lydi

Dewey number: 621.382

Index: index present

LC call number: TK7867.2

Literary form: non fiction

Nature of contents

dictionaries
bibliography

http://library.link/vocab/subjectName

Radio
Electromagnetic interference
Signal integrity (Electronics)
Telecommunication systems
Orthogonal frequency division multiplexing
TECHNOLOGY & ENGINEERING
Electromagnetic interference
Orthogonal frequency division multiplexing
Signal integrity (Electronics)
Telecommunication systems

Label: RF analog impairments modeling for communication systems simulation : application to OFDM-based transceivers, Lydi Smaini

Instantiates

RF analog impairments modeling for communication systems simulation : application to OFDM-based transceivers

Publication

Chichester, West Sussex, United Kingdom, Wiley, 2012

Note: Machine generated contents note: 1 Chapter 1: Introduction to Communication System- On-Chip, RF analog front-end, OFDM modulation, and performance metrics 1.1 Communication System-on-Chip 1.1.1 Introduction 1.1.2 CMOS technology 1.1.3 Coexistence Issues 1.2 RF Analog Front-End Overview 1.2.1 Introduction 1.2.2 Super-heterodyne transceiver 1.2.3 Homodyne transceiver 1.2.4 Low-IF transceiver 1.2.5 Analog baseband Filter order vs. ADC dynamic range 1.2.6 Digital compensation of RF Analog Front-End imperfections 1.3 OFDM modulation 1.3.1 OFDM as a Multicarrier modulation 1.3.2 Fourier Transform and Orthogonal Subcarriers 1.3.3 Channel estimation and equalization in frequency domain 1.3.4 Pilot-tones 1.3.5 Guard interval 1.3.6 Windowed OFDM 1.3.7 Adaptive Transmission 1.3.8 OFDMA for Multiple Access 1.3.9 Scalable OFDMA 1.3.10 OFDM digital baseband architecture 1.3.11 OFDM-based standards 1.4 SNR, EVM, and Eb/N0 definitions and relationship 1.4.1 Bit error rate 1.4.2 SNR vs. EVM 1.4.3 SNR vs. Eb/N0 1.4.4 Complex baseband representation 2 Chapter 2: RF Analog impairments description and modeling 2.1 Introduction 2.2 Thermal Noise 2.2.1 Additive White Gaussian Noise 2.2.2 Noise Figure and Sensitivity 2.2.3 Cascaded noise voltage in IC design 2.2.4 AWGN in simulations 2.2.5 Flicker Noise and AWGN modeling 2.3 Oscillator Phase Noise 2.3.1 Description and Impact on the system 2.3.2 Phase Noise Modeling in Frequency Domain 2.3.3 Simulation in Temporal Domain 2.3.4 SNR limitation due to the phase noise 2.3.5 Impact of phase noise in OFDM 2.4 Sampling jitter 2.4.1 Jitter definitions 2.4.2 Sampling jitter and phase noise relationship 2.4.3 SNR limitation due to sampling jitter 2.4.4 Impact of sampling jitter in OFDM 2.4.5 Sampling jitter modeling 2.5 Carrier Frequency Offset 2.5.1 Description 2.5.2 Impact of Carrier Frequency Offset in OFDM 2.6 Sampling Frequency Offset 2.6.1 Description 2.6.2 Impact of Sampling Frequency Offset in OFDM 2.7 I & Q mismatch 2.7.1 Description 2.7.2 IQ mismatch modeling 2.7.3 SNR limitation due to IQ mismatch 2.7.4 Impact of IQ mismatch in OFDM 2.8 DAC/ADC quantization noise and clipping 2.8.1 SNR limitation due to the quantization noise and clipping level 2.8.2 Impact of converter clipping level in OFDM 2.8.3 DAC and ADC dynamic range in OFDM 2.8.4 DAC and ADC modeling 2.9 IP2 and IP3: 2nd and 3rd Order non-linearities 2.9.1 Harmonics (Single-tone test) 2.9.2 Intermodulation Distortion (Two-tone test) 2.9.3 Receiver performance degradation due to the non-linearities 3 Chapter 3: Simulation of the RF Analog impairments impact on real OFDM-based transceivers performance 3.1 Introduction 3.2 WLAN and mobile WIMAX PHY overview 3.2.1 WLAN: Standard IEEE 802.11a/g 3.2.2 Mobile WiMAX: Standard IEEE 802.16e 3.3 Simulation bench overview 3.3.1 WiFi and WiMAX OFDM transceiver modeling 3.3.2 EVM estimation as performance metric 3.3.3 EVM vs. SNR simulations in AWGN channel 3.4 WiFi OFDM and mobile WiMAX signals PAPR 3.5 Transmitter impairments simulation 3.5.1 Introduction 3.5.2 DAC clipping and resolution 3.5.3 I & Q mismatch 3.5.4 RF oscillator phase noise 3.5.5 Power amplifier distortion 3.5.6 Transmitter complete simulation 3.6 Receiver impairments simulation 3.6.1 Introduction 3.6.2 Carrier Frequency Offset 3.6.3 Sampling Frequency Offset 3.6.4 Linearity: IIP2 and IIP3 3.6.5 I & Q mismatch 3.6.6 RF oscillator phase noise and reciprocal mixing 3.6.7 Sampling jitter 3.6.8 ADC clipping and resolution 3.6.9 Receiver complete simulation 3.7 Adaptive modulation illustration 3.8 Summary 4 Chapter 4: Digital Compensation of RF analog Impairments 4.1 Introduction 4.2 Carrier Frequency Offset Estimation and Correction 4.2.1 CFO estimation principle 4.2.2 CFO estimation in time domain 4.2.3 CFO estimation in frequency domain 4.2.4 CFO correction 4.3 Sampling Frequency Offset Estimation and Correction 4.3.1 SFO estimation principle 4.3.2 SFO estimation 4.3.3 SFO correction 4.3.4 Joint SFO and CFO estimation 4.4 IQ mismatch estimation and correction 4.4.1 Principle 4.4.2 Effect of the channel 4.4.3 Simulation results 4.5 Power Amplifier Linearization 4.5.1 Digital Predistortion Principle 4.5.2 Memory polynomial predistortion 4.5.3 Polynomial coefficients computation 4.5.4 Simulation results 4.6 Summary

Bibliography note: Includes bibliographical references and index

Carrier category: online resource

Carrier category code

Carrier MARC source: rdacarrier

Content category: text

Content type code

Content type MARC source: rdacontent

Contents

CMOS Technology
2.4.5.
Sampling Jitter Modeling
2.5.
Carrier Frequency Offset
2.5.1.
Description
2.5.2.
Impact of CFO in OFDM
2.6.
Sampling Frequency Offset
1.1.3.
2.6.1.
Description
2.6.2.
Impact of SFO in OFDM
2.7.
I and Q Mismatch
2.7.1.
Description
2.7.2.
IQ Mismatch Modeling
Coexistence Issues
2.7.3.
SNR Limitation due to IQ Mismatch
2.7.4.
Impact of IQ Mismatch in OFDM
2.8.
DAC/ADC Quantization Noise and Clipping
2.8.1.
SNR Limitation due to the Quantization Noise and Clipping Level
2.8.2.
Impact of Converter Clipping Level in OFDM
1.2.
2.8.3.
DAC and ADC Dynamic Range in OFDM
2.8.4.
DAC and ADC Modeling
2.9.
IP2 and IP3: Second- and Third-Order Nonlinearities
2.9.1.
Harmonics (Single-Tone Test)
2.9.2.
Intermodulation Distortion (Two-Tone Test)
RF AFE Overview
2.9.3.
Receiver Performance Degradation due to the Non-linearities
2.9.4.
Impact of Third-Order Nonlinearity in OFDM
2.9.5.
Simulation in Complex Baseband
2.10.
Power Amplifier Distortion
2.10.1.
PA Modeling
1.2.1.
2.10.2.
Impact of PA Distortions in OFDM
References
3.
Simulation of the RF Analog Impairments Impact on Real OFDM-Based Transceiver Performance
3.1.
Introduction
3.2.
WLAN and Mobile WiMAX PHY Overview
3.2.1.
Introduction
WLAN: Standard IEEE 802.11a/g
3.2.2.
Mobile WiMAX: Standard IEEE 802.16e
3.3.
Simulation Bench Overview
3.3.1.
WiFi and WiMAX OFDM Transceiver Modeling
3.3.2.
EVM Estimation as Performance Metric
3.3.3.
1.2.2.
EVM versus SNR Simulations in AWGN Channel
3.4.
WiFi OFDM and Mobile WiMAX Signals PAPR
3.5.
Transmitter Impairments Simulation
3.5.1.
Introduction
3.5.2.
DAC Clipping and Resolution
3.5.3.
Superheterodyne Transceiver
I and Q Mismatch
3.5.4.
RF Oscillator Phase Noise
3.5.5.
Power Amplifier Distortion
3.5.6.
Transmitter Complete Simulation
3.6.
Receiver Impairments Simulation
3.6.1.
1.2.3.
Introduction
3.6.2.
Carrier Frequency Offset
3.6.3.
Sampling Frequency Offset
3.6.4.
Linearity: IIP2 and IIP3
3.6.5.
I and Q Mismatch
3.6.6.
Machine generated contents note:
Homodyne Transceiver
RF Oscillator Phase Noise and Reciprocal Mixing
3.6.7.
Sampling Jitter
3.6.8.
ADC Clipping and Resolution
3.6.9.
Receiver Complete Simulation
3.7.
Adaptive Modulation Illustration
3.8.
1.2.4.
Summary
References
4.
Digital Compensation of RF Analog Impairments
4.1.
Introduction
4.2.
CFO Estimation and Correction
4.2.1.
CFO Estimation Principle
Low-IF Transceiver
4.2.2.
CFO Estimation in the Time Domain
4.2.3.
CFO Estimation in the Frequency Domain
4.2.4.
CFO Correction
4.3.
SFO Estimation and Correction
4.3.1.
SFO Estimation Principle
1.2.5.
4.3.2.
SFO Estimation
4.3.3.
SFO Correction
4.3.4.
Joint SFO and CFO Estimation
4.4.
IQ Mismatch Estimation and Correction
4.4.1.
Principle
Analog Baseband Filter Order versus ADC Dynamic Range
4.4.2.
Effect of the Channel
4.4.3.
Simulation Results
4.5.
Power Amplifier Linearization
4.5.1.
Digital Predistortion Principle
4.5.2.
Memory Polynomial Predistortion
1.2.6.
4.5.3.
Polynomial Coefficients Computation
4.5.4.
Simulation Results
4.6.
Summary
References
Digital Compensation of RF Analog Front-End Imperfections
1.3.
OFDM Modulation
1.3.1.
1.
OFDM as a Multicarrier Modulation
1.3.2.
Fourier Transform and Orthogonal Subcarriers
1.3.3.
Channel Estimation and Equalization in Frequency Domain
1.3.4.
Pilot-Tones
1.3.5.
Guard Interval
1.3.6.
Introduction to Communication System-on-Chip, RF Analog Front-End, OFDM Modulation, and Performance Metrics
Windowed OFDM
1.3.7.
Adaptive Transmission
1.3.8.
OFDMA for Multiple Access
1.3.9.
Scalable OFDMA
1.3.10.
OFDM DBB Architecture
1.3.11.
1.1.
OFDM-Based Standards
1.4.
SNR, EVM, and Eb/No Definitions and Relationship
1.4.1.
Bit Error Rate
1.4.2.
SNR versus EVM
1.4.3.
SNR versus Eb/No
1.4.4.
Communication System-on-Chip
Complex Baseband Representation
References
2.
RF Analog Impairments Description and Modeling
2.1.
Introduction
2.2.
Thermal Noise
2.2.1.
Additive White Gaussian Noise
1.1.1.
2.2.2.
Noise Figure and Sensitivity
2.2.3.
Cascaded Noise Voltage in IC Design
2.2.4.
AWGN in Simulations
2.2.5.
Flicker Noise and AWGN Modeling
2.3.
Oscillator Phase Noise
Introduction
2.3.1.
Description and Impact on the System
2.3.2.
Phase Noise Modeling in the Frequency Domain
2.3.3.
Simulation in Temporal Domain
2.3.4.
SNR Limitation due to the Phase Noise
2.3.5.
Impact of Phase Noise in OFDM
1.1.2.
2.4.
Sampling Jitter
2.4.1.
Jitter Definitions
2.4.2.
Sampling Jitter and Phase Noise Relationship
2.4.3.
SNR Limitation due to Sampling Jitter
2.4.4.
Impact of Sampling Jitter in OFDM

Control code: 795020567

Dimensions: unknown

Extent: 1 online resource

Form of item: online

Isbn: 9781283645157

Lccn: 2012023393

Media category: computer

Media MARC source: rdamedia

Media type code

http://library.link/vocab/ext/overdrive/overdriveId: 395765

Specific material designation: remote

System control number: (OCoLC)795020567

Label: RF analog impairments modeling for communication systems simulation : application to OFDM-based transceivers, Lydi Smaini

Publication

Chichester, West Sussex, United Kingdom, Wiley, 2012

Note: Machine generated contents note: 1 Chapter 1: Introduction to Communication System- On-Chip, RF analog front-end, OFDM modulation, and performance metrics 1.1 Communication System-on-Chip 1.1.1 Introduction 1.1.2 CMOS technology 1.1.3 Coexistence Issues 1.2 RF Analog Front-End Overview 1.2.1 Introduction 1.2.2 Super-heterodyne transceiver 1.2.3 Homodyne transceiver 1.2.4 Low-IF transceiver 1.2.5 Analog baseband Filter order vs. ADC dynamic range 1.2.6 Digital compensation of RF Analog Front-End imperfections 1.3 OFDM modulation 1.3.1 OFDM as a Multicarrier modulation 1.3.2 Fourier Transform and Orthogonal Subcarriers 1.3.3 Channel estimation and equalization in frequency domain 1.3.4 Pilot-tones 1.3.5 Guard interval 1.3.6 Windowed OFDM 1.3.7 Adaptive Transmission 1.3.8 OFDMA for Multiple Access 1.3.9 Scalable OFDMA 1.3.10 OFDM digital baseband architecture 1.3.11 OFDM-based standards 1.4 SNR, EVM, and Eb/N0 definitions and relationship 1.4.1 Bit error rate 1.4.2 SNR vs. EVM 1.4.3 SNR vs. Eb/N0 1.4.4 Complex baseband representation 2 Chapter 2: RF Analog impairments description and modeling 2.1 Introduction 2.2 Thermal Noise 2.2.1 Additive White Gaussian Noise 2.2.2 Noise Figure and Sensitivity 2.2.3 Cascaded noise voltage in IC design 2.2.4 AWGN in simulations 2.2.5 Flicker Noise and AWGN modeling 2.3 Oscillator Phase Noise 2.3.1 Description and Impact on the system 2.3.2 Phase Noise Modeling in Frequency Domain 2.3.3 Simulation in Temporal Domain 2.3.4 SNR limitation due to the phase noise 2.3.5 Impact of phase noise in OFDM 2.4 Sampling jitter 2.4.1 Jitter definitions 2.4.2 Sampling jitter and phase noise relationship 2.4.3 SNR limitation due to sampling jitter 2.4.4 Impact of sampling jitter in OFDM 2.4.5 Sampling jitter modeling 2.5 Carrier Frequency Offset 2.5.1 Description 2.5.2 Impact of Carrier Frequency Offset in OFDM 2.6 Sampling Frequency Offset 2.6.1 Description 2.6.2 Impact of Sampling Frequency Offset in OFDM 2.7 I & Q mismatch 2.7.1 Description 2.7.2 IQ mismatch modeling 2.7.3 SNR limitation due to IQ mismatch 2.7.4 Impact of IQ mismatch in OFDM 2.8 DAC/ADC quantization noise and clipping 2.8.1 SNR limitation due to the quantization noise and clipping level 2.8.2 Impact of converter clipping level in OFDM 2.8.3 DAC and ADC dynamic range in OFDM 2.8.4 DAC and ADC modeling 2.9 IP2 and IP3: 2nd and 3rd Order non-linearities 2.9.1 Harmonics (Single-tone test) 2.9.2 Intermodulation Distortion (Two-tone test) 2.9.3 Receiver performance degradation due to the non-linearities 3 Chapter 3: Simulation of the RF Analog impairments impact on real OFDM-based transceivers performance 3.1 Introduction 3.2 WLAN and mobile WIMAX PHY overview 3.2.1 WLAN: Standard IEEE 802.11a/g 3.2.2 Mobile WiMAX: Standard IEEE 802.16e 3.3 Simulation bench overview 3.3.1 WiFi and WiMAX OFDM transceiver modeling 3.3.2 EVM estimation as performance metric 3.3.3 EVM vs. SNR simulations in AWGN channel 3.4 WiFi OFDM and mobile WiMAX signals PAPR 3.5 Transmitter impairments simulation 3.5.1 Introduction 3.5.2 DAC clipping and resolution 3.5.3 I & Q mismatch 3.5.4 RF oscillator phase noise 3.5.5 Power amplifier distortion 3.5.6 Transmitter complete simulation 3.6 Receiver impairments simulation 3.6.1 Introduction 3.6.2 Carrier Frequency Offset 3.6.3 Sampling Frequency Offset 3.6.4 Linearity: IIP2 and IIP3 3.6.5 I & Q mismatch 3.6.6 RF oscillator phase noise and reciprocal mixing 3.6.7 Sampling jitter 3.6.8 ADC clipping and resolution 3.6.9 Receiver complete simulation 3.7 Adaptive modulation illustration 3.8 Summary 4 Chapter 4: Digital Compensation of RF analog Impairments 4.1 Introduction 4.2 Carrier Frequency Offset Estimation and Correction 4.2.1 CFO estimation principle 4.2.2 CFO estimation in time domain 4.2.3 CFO estimation in frequency domain 4.2.4 CFO correction 4.3 Sampling Frequency Offset Estimation and Correction 4.3.1 SFO estimation principle 4.3.2 SFO estimation 4.3.3 SFO correction 4.3.4 Joint SFO and CFO estimation 4.4 IQ mismatch estimation and correction 4.4.1 Principle 4.4.2 Effect of the channel 4.4.3 Simulation results 4.5 Power Amplifier Linearization 4.5.1 Digital Predistortion Principle 4.5.2 Memory polynomial predistortion 4.5.3 Polynomial coefficients computation 4.5.4 Simulation results 4.6 Summary

Bibliography note: Includes bibliographical references and index

Carrier category: online resource

Carrier category code

Carrier MARC source: rdacarrier

Content category: text

Content type code

Content type MARC source: rdacontent

Contents

CMOS Technology
2.4.5.
Sampling Jitter Modeling
2.5.
Carrier Frequency Offset
2.5.1.
Description
2.5.2.
Impact of CFO in OFDM
2.6.
Sampling Frequency Offset
1.1.3.
2.6.1.
Description
2.6.2.
Impact of SFO in OFDM
2.7.
I and Q Mismatch
2.7.1.
Description
2.7.2.
IQ Mismatch Modeling
Coexistence Issues
2.7.3.
SNR Limitation due to IQ Mismatch
2.7.4.
Impact of IQ Mismatch in OFDM
2.8.
DAC/ADC Quantization Noise and Clipping
2.8.1.
SNR Limitation due to the Quantization Noise and Clipping Level
2.8.2.
Impact of Converter Clipping Level in OFDM
1.2.
2.8.3.
DAC and ADC Dynamic Range in OFDM
2.8.4.
DAC and ADC Modeling
2.9.
IP2 and IP3: Second- and Third-Order Nonlinearities
2.9.1.
Harmonics (Single-Tone Test)
2.9.2.
Intermodulation Distortion (Two-Tone Test)
RF AFE Overview
2.9.3.
Receiver Performance Degradation due to the Non-linearities
2.9.4.
Impact of Third-Order Nonlinearity in OFDM
2.9.5.
Simulation in Complex Baseband
2.10.
Power Amplifier Distortion
2.10.1.
PA Modeling
1.2.1.
2.10.2.
Impact of PA Distortions in OFDM
References
3.
Simulation of the RF Analog Impairments Impact on Real OFDM-Based Transceiver Performance
3.1.
Introduction
3.2.
WLAN and Mobile WiMAX PHY Overview
3.2.1.
Introduction
WLAN: Standard IEEE 802.11a/g
3.2.2.
Mobile WiMAX: Standard IEEE 802.16e
3.3.
Simulation Bench Overview
3.3.1.
WiFi and WiMAX OFDM Transceiver Modeling
3.3.2.
EVM Estimation as Performance Metric
3.3.3.
1.2.2.
EVM versus SNR Simulations in AWGN Channel
3.4.
WiFi OFDM and Mobile WiMAX Signals PAPR
3.5.
Transmitter Impairments Simulation
3.5.1.
Introduction
3.5.2.
DAC Clipping and Resolution
3.5.3.
Superheterodyne Transceiver
I and Q Mismatch
3.5.4.
RF Oscillator Phase Noise
3.5.5.
Power Amplifier Distortion
3.5.6.
Transmitter Complete Simulation
3.6.
Receiver Impairments Simulation
3.6.1.
1.2.3.
Introduction
3.6.2.
Carrier Frequency Offset
3.6.3.
Sampling Frequency Offset
3.6.4.
Linearity: IIP2 and IIP3
3.6.5.
I and Q Mismatch
3.6.6.
Machine generated contents note:
Homodyne Transceiver
RF Oscillator Phase Noise and Reciprocal Mixing
3.6.7.
Sampling Jitter
3.6.8.
ADC Clipping and Resolution
3.6.9.
Receiver Complete Simulation
3.7.
Adaptive Modulation Illustration
3.8.
1.2.4.
Summary
References
4.
Digital Compensation of RF Analog Impairments
4.1.
Introduction
4.2.
CFO Estimation and Correction
4.2.1.
CFO Estimation Principle
Low-IF Transceiver
4.2.2.
CFO Estimation in the Time Domain
4.2.3.
CFO Estimation in the Frequency Domain
4.2.4.
CFO Correction
4.3.
SFO Estimation and Correction
4.3.1.
SFO Estimation Principle
1.2.5.
4.3.2.
SFO Estimation
4.3.3.
SFO Correction
4.3.4.
Joint SFO and CFO Estimation
4.4.
IQ Mismatch Estimation and Correction
4.4.1.
Principle
Analog Baseband Filter Order versus ADC Dynamic Range
4.4.2.
Effect of the Channel
4.4.3.
Simulation Results
4.5.
Power Amplifier Linearization
4.5.1.
Digital Predistortion Principle
4.5.2.
Memory Polynomial Predistortion
1.2.6.
4.5.3.
Polynomial Coefficients Computation
4.5.4.
Simulation Results
4.6.
Summary
References
Digital Compensation of RF Analog Front-End Imperfections
1.3.
OFDM Modulation
1.3.1.
1.
OFDM as a Multicarrier Modulation
1.3.2.
Fourier Transform and Orthogonal Subcarriers
1.3.3.
Channel Estimation and Equalization in Frequency Domain
1.3.4.
Pilot-Tones
1.3.5.
Guard Interval
1.3.6.
Introduction to Communication System-on-Chip, RF Analog Front-End, OFDM Modulation, and Performance Metrics
Windowed OFDM
1.3.7.
Adaptive Transmission
1.3.8.
OFDMA for Multiple Access
1.3.9.
Scalable OFDMA
1.3.10.
OFDM DBB Architecture
1.3.11.
1.1.
OFDM-Based Standards
1.4.
SNR, EVM, and Eb/No Definitions and Relationship
1.4.1.
Bit Error Rate
1.4.2.
SNR versus EVM
1.4.3.
SNR versus Eb/No
1.4.4.
Communication System-on-Chip
Complex Baseband Representation
References
2.
RF Analog Impairments Description and Modeling
2.1.
Introduction
2.2.
Thermal Noise
2.2.1.
Additive White Gaussian Noise
1.1.1.
2.2.2.
Noise Figure and Sensitivity
2.2.3.
Cascaded Noise Voltage in IC Design
2.2.4.
AWGN in Simulations
2.2.5.
Flicker Noise and AWGN Modeling
2.3.
Oscillator Phase Noise
Introduction
2.3.1.
Description and Impact on the System
2.3.2.
Phase Noise Modeling in the Frequency Domain
2.3.3.
Simulation in Temporal Domain
2.3.4.
SNR Limitation due to the Phase Noise
2.3.5.
Impact of Phase Noise in OFDM
1.1.2.
2.4.
Sampling Jitter
2.4.1.
Jitter Definitions
2.4.2.
Sampling Jitter and Phase Noise Relationship
2.4.3.
SNR Limitation due to Sampling Jitter
2.4.4.
Impact of Sampling Jitter in OFDM

Control code: 795020567

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Isbn: 9781283645157

Lccn: 2012023393

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System control number: (OCoLC)795020567

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