Signal Processing and Integrated Circuits
(Sprache: Englisch)
This book provides a balanced account of analog, digital and mixed-mode signal processing with applications in telecommunications. Part I Perspective gives an overview of the areas of Systems on a Chip (Soc) and mobile communication which are used to...
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Produktinformationen zu „Signal Processing and Integrated Circuits “
This book provides a balanced account of analog, digital and mixed-mode signal processing with applications in telecommunications. Part I Perspective gives an overview of the areas of Systems on a Chip (Soc) and mobile communication which are used to demonstrate the complementary relationship between analog and digital systems. Part II Analog (continuous-time) and Digital Signal Processing contains both fundamental and advanced analysis, and design techniques, of analog and digital systems. This includes analog and digital filter design; fast Fourier transform (FFT) algorithms; stochastic signals; linear estimation and adaptive filters. Part III Analog MOS Integrated Circuits for Signal Processing covers basic MOS transistor operation and fabrication through to the design of complex integrated circuits such as high performance Op Amps, Operational Transconductance Amplifiers (OTA's) and Gm-C circuits. Part IV Switched-capacitor and Mixed-mode Signal Processing outlines the design of switched-capacitor filters, and concludes with sigma-delta data converters as an extensive application of analog and digital signal processing
- Contains the fundamentals and advanced techniques of continuous-time and discrete-time signal processing.
- Presents in detail the design of analog MOS integrated circuits for signal processing, with application to the design of switched-capacitor filters.
- Uses the comprehensive design of integrated sigma-delta data converters to illustrate and unify the techniques of signal processing.
- Includes solved examples, end of chapter problems and MATLAB(r) throughout the book, to help readers understand the mathematical complexities of signal processing.
The treatment of the topic is at the senior undergraduate to graduate and professional levels, with sufficient introductory material for the book to be used as a self-contained reference.d-mode Signal Processing outlines the design of switched-capacitor filters
- Contains the fundamentals and advanced techniques of continuous-time and discrete-time signal processing.
- Presents in detail the design of analog MOS integrated circuits for signal processing, with application to the design of switched-capacitor filters.
- Uses the comprehensive design of integrated sigma-delta data converters to illustrate and unify the techniques of signal processing.
- Includes solved examples, end of chapter problems and MATLAB(r) throughout the book, to help readers understand the mathematical complexities of signal processing.
The treatment of the topic is at the senior undergraduate to graduate and professional levels, with sufficient introductory material for the book to be used as a self-contained reference.d-mode Signal Processing outlines the design of switched-capacitor filters
Klappentext zu „Signal Processing and Integrated Circuits “
This book provides a balanced account of analog, digital and mixed-mode signal processing with applications in telecommunications. Part I Perspective gives an overview of the areas of Systems on a Chip (Soc) and mobile communication which are used to demonstrate the complementary relationship between analog and digital systems. Part II Analog (continuous-time) and Digital Signal Processing contains both fundamental and advanced analysis, and design techniques, of analog and digital systems. This includes analog and digital filter design; fast Fourier transform (FFT) algorithms; stochastic signals; linear estimation and adaptive filters. Part III Analog MOS Integrated Circuits for Signal Processing covers basic MOS transistor operation and fabrication through to the design of complex integrated circuits such as high performance Op Amps, Operational Transconductance Amplifiers (OTA's) and Gm-C circuits. Part IV Switched-capacitor and Mixed-mode Signal Processing outlines the designof switched-capacitor filters, and concludes with sigma-delta data converters as an extensive application of analog and digital signal processing Contains the fundamentals and advanced techniques of continuous-time and discrete-time signal processing. Presents in detail the design of analog MOS integrated circuits for signal processing, with application to the design of switched-capacitor filters. Uses the comprehensive design of integrated sigma-delta data converters to illustrate and unify the techniques of signal processing. Includes solved examples, end of chapter problems and MATLAB(r) throughout the book, to help readers understand the mathematical complexities of signal processing.The treatment of the topic is at the senior undergraduate to graduate and professional levels, with sufficient introductory material for the book to be used as a self-contained reference.
Inhaltsverzeichnis zu „Signal Processing and Integrated Circuits “
PART I PERSPECTIVE 1. Analog, Digital and Mixed-mode Signal Processing
1.1 Digital Signal Processing
1.2 Moore's Law and the "Cleverness" Factor
1.3 System on a Chip
1.4 Analog and Mixed-mode Signal Processing
1.5 Scope
PART II ANALOG (CONTINUOUS-TIME) AND DIGITAL SIGNAL PROCESSING
2. Analog Signals and Systems
2.1 Introduction
2.2 The Fourier Series in Spectral analysis and Function Approximation
2.3 The Fourier Transformation
2.4 The Laplace Transform and Analog Systems
2.5 Elementary Signal Processing Building Blocks
2.6 Realization of Analog System Functions
2.7 Conclusion Problems.
3. Design of Analog Filters
3.1 Introduction
3.2 The Filter Design Problem
3.3 Amplitude-oriented Design
3.4 Frequency Transformations
3.5 Examples
3.6 Phase-oriented Design
3.7 Passive Filters
3.8 Active Filters
3.9 Use of MATLAB(r) for the Design of Analog Filters
3.10 Examples of the Use of MATLAB(r)
3.11 A Comprehensive Application: Design of Pulse -shaping Filters for Data Transmission
3.12 Conclusion Problems
4. Discrete Signals and Systems
4.1 Introduction
4.2 Digitization of Analog Signals
4.3 Discrete Signals and Systems
4.4 Digital Filters
4.5 Conclusion Problems
5. Design of Digital Filters
5.1 Introduction
5.2 General Considerations
5.3 Amplitude-oriented Design of IIR Filters
5.4 Phase-oriented Design of IIR Filters
5.5 FIR Filters
5.6 Comparison between IIR and FIR Filters
5.7 Use of MATLAB(r) for the Design of Digital Filters
5.8 A Comprehensive Application: Pulse Shaping for Data Transmission
5.9 Conclusion Problems
6. The Fast Fourier Transform and its Applications
6.1 Introduction
6.2 Periodic Signals
6.3 Non-periodic Signals
6.4 The Discrete Fourier transform(DFT)
6.5 The Fast Fourier Transform (FFT) Algorithms
6.6 Properties of Discrete Fourier Transform
6.7 Spectral Analysis Using the FFT
6.8 Spectral Windows
6.9 Fast Convolution, Filtering and Correlation
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using the FFT
6.10 Use of MATLAB(r)
6.11 Conclusion Problems 7 Stochastic Signals and Power Spectra
7.1 Introduction
7.2 Random Variables
7.3 Analog Stochastic Processes
7.4 Discrete-time Stochastic Signals
7.5 Power Spectrum Estimation
7.6 Conclusion Problems 8 Finite Word-length Effects in Digital Processors
8.1 Introduction
8.2 Input Signal Quantization Errors
8.3 Coefficient Quantization Effects
8.4 Effect of Round-off Accumulation
8.5 Auto-Oscillations : Overflow and Limit Cycles
8.6 Conclusion Problems 9 Linear Estimation, System Modelling and Adaptive Filters
9.1 Introduction
9.2 Mean-square Approximation
9.3 Linear Estimation, Modelling and Optimum Filters
9.4 Optimum Minimum Mean Square Error Analog Estimation
9.5 The Matched Filter
9.6 Discrete-time Linear Estimation
9.7 Adaptive IIR Filtering and System Modelling
9.8 An Application of Adaptive Filters: Echo Cancellation in the Satellite Transmission of Speech Signals.
9.9 Conclusion
PART III Analog MOS Integrated Circuits For Signal Processing
10. The MOS Transistor and Integrated Circuit Fabrication
10.1 Introduction
10.2 The MOS Transistor
10.3 Integrated Circuit Fabrication
10.4 Layout and Area Considerations for IC MOSFETs
10.5 Noise in MOSFETs Problems
11. Basic Integrated Circuit Building Blocks
11.1 Introduction
11.2 MOS Active Resistors and Load Devices
11.3 MOS Amplifiers
11.4 High Frequency Considerations
11.5 The Current Mirror
11.6 The CMOS Amplifier
11.7 Conclusion Problems
12. Two-Stage CMOS Operational Amplifiers
12.1 Introduction
12.2 Op Amp Performance Parameters
12.3 Feedback Amplifiers Fundamentals
12.4 The CMOS Differential Amplifier
12.5 The Two-stage CMOS Op Amp
12.6 Practical Considerations and Other Non-Ideal Effects in Op Amp Design Problems
13. High-Performance Operational Amplifiers and Operational Transconductance Amplifiers
13.1 Introduction
13.2 Cascode CMOS Op Amps
13.3 The Folded Cascode Operational Amplifiers
13.4 Low-noise Operational Amplifiers
13.5 High -frequency Operational Amplifiers
13.6 Fully-differential Balanced T0pology
13.7 Operational Transconductance Amplifiers (OTAs)
13.8 Conclusion Problems
14. Capacitors, Switches and the Occasional Passive Resistor
14.1 Introduction
14.2 MOS Capacitors
14.3 The MOS Switch
14.4 MOS Passive resistors
14.5 Conclusion Problems
PART IV Switched-capacitor and Mixed-mode Signal Processing
15. Design of Microelectronic Switched-capacitor Filters
15.1 Motivation
15.2 Sampled-and- held -signals
15.3 Amplitude-oriented Design of Filters of the Lossless Discrete Integrator (LDI) type
15.4 Filters Derived from Passive Lumped Prototypes
15.5 Cascade Design
15.6 Applications in Telecommunications
15.7 Conclusion
16. Non-ideal Effects and Practical Considerations in Microelectronic Switched-capacitor Filters
16.1 Introduction
16.2 Effect of Finite Op Amp Gain
16.3 Effect of Finite Bandwidth and Slew Rate of Op Amps
16.4 Effect of Finite Op Amp Output Resistance
16.5 Scaling for Maximum Dynamic Range
16.6 Scaling for Minimum Capacitance
16.7 Fully Differential Balanced Design
16.8 More on Parasitic Capacitance and Switch Noise
16.9 Pre-filtering and Post-filtering
16.10 Programmable Filters
16.11 Layout Considerations
16.12 Conclusion
17. Integrated Sigma Delta Data Converters: Extension and Comprehensive Application of Analog and Digital Signal Processing
17.1 Motivation and General Introduction
17.2 The First-order Converter
17.3 The Second-order Converter
17.4 Decimation and Digital Filtering
17.5 Simulation and Performance Evaluation
17.6 A Case Study: Fourth Order Converter
17.7 Conclusion Microelectronic Switched-capacitor Filters
16.1 Introduction
16.2 Effect of Finite Op Amp Gain
16.3 Effect of Finite Bandwidth and Slew Rate of Op Amps
16.4 Effect of Finite Op Amp Output Resistance
16.5 Scaling for Maximum Dynamic Range
16.6 Scaling for Minimum Capacitance
16.7 Fully Differential Balanced Design
16.8 Mo
6.10 Use of MATLAB(r)
6.11 Conclusion Problems 7 Stochastic Signals and Power Spectra
7.1 Introduction
7.2 Random Variables
7.3 Analog Stochastic Processes
7.4 Discrete-time Stochastic Signals
7.5 Power Spectrum Estimation
7.6 Conclusion Problems 8 Finite Word-length Effects in Digital Processors
8.1 Introduction
8.2 Input Signal Quantization Errors
8.3 Coefficient Quantization Effects
8.4 Effect of Round-off Accumulation
8.5 Auto-Oscillations : Overflow and Limit Cycles
8.6 Conclusion Problems 9 Linear Estimation, System Modelling and Adaptive Filters
9.1 Introduction
9.2 Mean-square Approximation
9.3 Linear Estimation, Modelling and Optimum Filters
9.4 Optimum Minimum Mean Square Error Analog Estimation
9.5 The Matched Filter
9.6 Discrete-time Linear Estimation
9.7 Adaptive IIR Filtering and System Modelling
9.8 An Application of Adaptive Filters: Echo Cancellation in the Satellite Transmission of Speech Signals.
9.9 Conclusion
PART III Analog MOS Integrated Circuits For Signal Processing
10. The MOS Transistor and Integrated Circuit Fabrication
10.1 Introduction
10.2 The MOS Transistor
10.3 Integrated Circuit Fabrication
10.4 Layout and Area Considerations for IC MOSFETs
10.5 Noise in MOSFETs Problems
11. Basic Integrated Circuit Building Blocks
11.1 Introduction
11.2 MOS Active Resistors and Load Devices
11.3 MOS Amplifiers
11.4 High Frequency Considerations
11.5 The Current Mirror
11.6 The CMOS Amplifier
11.7 Conclusion Problems
12. Two-Stage CMOS Operational Amplifiers
12.1 Introduction
12.2 Op Amp Performance Parameters
12.3 Feedback Amplifiers Fundamentals
12.4 The CMOS Differential Amplifier
12.5 The Two-stage CMOS Op Amp
12.6 Practical Considerations and Other Non-Ideal Effects in Op Amp Design Problems
13. High-Performance Operational Amplifiers and Operational Transconductance Amplifiers
13.1 Introduction
13.2 Cascode CMOS Op Amps
13.3 The Folded Cascode Operational Amplifiers
13.4 Low-noise Operational Amplifiers
13.5 High -frequency Operational Amplifiers
13.6 Fully-differential Balanced T0pology
13.7 Operational Transconductance Amplifiers (OTAs)
13.8 Conclusion Problems
14. Capacitors, Switches and the Occasional Passive Resistor
14.1 Introduction
14.2 MOS Capacitors
14.3 The MOS Switch
14.4 MOS Passive resistors
14.5 Conclusion Problems
PART IV Switched-capacitor and Mixed-mode Signal Processing
15. Design of Microelectronic Switched-capacitor Filters
15.1 Motivation
15.2 Sampled-and- held -signals
15.3 Amplitude-oriented Design of Filters of the Lossless Discrete Integrator (LDI) type
15.4 Filters Derived from Passive Lumped Prototypes
15.5 Cascade Design
15.6 Applications in Telecommunications
15.7 Conclusion
16. Non-ideal Effects and Practical Considerations in Microelectronic Switched-capacitor Filters
16.1 Introduction
16.2 Effect of Finite Op Amp Gain
16.3 Effect of Finite Bandwidth and Slew Rate of Op Amps
16.4 Effect of Finite Op Amp Output Resistance
16.5 Scaling for Maximum Dynamic Range
16.6 Scaling for Minimum Capacitance
16.7 Fully Differential Balanced Design
16.8 More on Parasitic Capacitance and Switch Noise
16.9 Pre-filtering and Post-filtering
16.10 Programmable Filters
16.11 Layout Considerations
16.12 Conclusion
17. Integrated Sigma Delta Data Converters: Extension and Comprehensive Application of Analog and Digital Signal Processing
17.1 Motivation and General Introduction
17.2 The First-order Converter
17.3 The Second-order Converter
17.4 Decimation and Digital Filtering
17.5 Simulation and Performance Evaluation
17.6 A Case Study: Fourth Order Converter
17.7 Conclusion Microelectronic Switched-capacitor Filters
16.1 Introduction
16.2 Effect of Finite Op Amp Gain
16.3 Effect of Finite Bandwidth and Slew Rate of Op Amps
16.4 Effect of Finite Op Amp Output Resistance
16.5 Scaling for Maximum Dynamic Range
16.6 Scaling for Minimum Capacitance
16.7 Fully Differential Balanced Design
16.8 Mo
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Autoren-Porträt von Hussein Baher
PROFESSOR H. BAHER obtained his Ph.D. in Electronic Engineering from University College Dublin and held academic positions at universities worldwide including University College Dublin, Virginia Polytechnic Institute and State University, the Professorship of Electronic Engineering at Dublin City University, and the prestigious Analog Devices Professorship in Massachusetts, USA. He has published four books: Synthesis of Electrical Networks (Wiley, 1984), Selective Linear-phase Switched-capacitor and Digital Filters (Kluwer 1993), Microelectronic Switched-capacitor Filters: with ISICAP: a Computer-aided Design Package (Wiley, 1996), and the highly regarded first edition of the present book. He is a Chartered Engineer in Ireland and the UK and a Fellow of the IEI.Bibliographische Angaben
- Autor: Hussein Baher
- 2012, 1. Auflage., 472 Seiten, Maße: 17,4 x 25,3 cm, Gebunden, Englisch
- Verlag: Wiley & Sons
- ISBN-10: 0470710268
- ISBN-13: 9780470710265
- Erscheinungsdatum: 10.04.2012
Sprache:
Englisch
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