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前輩先進 大家好 分享Practical Applications in Digital Signal Processing 不太會用論壇上傳 15天期限 請管理員樓主幫忙~~下載網址 https://www.mediafire.com/file/f ... 52BNewbold.rar/file
About the AuthorRichard Newbold has been a digital hardware design engineer for more than thirty years. His designs have included special-purpose signal processing computers and systems, multirate filters, direct sequence spread spectrum processors, high-speed gallium arsenide ASIC design, wideband channelizers, fault-tolerant signal processors, adaptive beam forming, data lock loops, multirate PCM processing, adaptive filters, tuners, frequency synthesizers, digital automatic gain control, and much more. His practical design experience encompasses every topic covered in this text.
Contents
Preface
Acknowledgments
About the Author
1 Review of Digital Frequency
1.1 Definitions
1.2 Defining Digital Frequencies
1.3 Mathematical Representation of Digital Frequencies
1.4 Normalized Frequency
1.5 Representation of Digital Frequencies
2 Review of Complex Variables
2.1 Cartesian Form of Complex Numbers
2.2 Polar Form of Complex Numbers
2.3 Roots of Complex Numbers
2.4 Absolute Value of Complex Numbers
2.5 Exponential Form of Complex Numbers
2.6 Graphs of the Complex Variable z
2.7 Limits
2.8 Analytic Functions
2.9 Singularity
2.10 Entire Functions
2.11 The Complex Number ∞
2.12 Complex Differentiation
2.13 Cauchy-Riemann Equations
2.14 Simply Connected Region
2.15 Contours
2.16 Line Integrals
2.17 Real Line Integrals
2.18 Complex Line Integrals
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2.19 Cauchy’s Theorem
2.20 Table of Common Integrals
2.21 Cauchy’s Integral
2.22 Residue Theory
2.23 References
3 Review of the Fourier Transform
3.1 A Brief Review of the Fourier Series
3.2 A Brief Review of the Fourier Transform
3.3 Review of the Discrete Fourier Transform (DFT)
3.4 DFT Processing Gain
3.5 Example DFT Signal Processing Application
3.6 Discrete Time Fourier Transform (DTFT)
3.7 Fast Fourier Transform (FFT)
3.8 References
4 Review of the Z-Transform
4.1 Complex Number Representation
4.2 Mechanics of the Z-Transform
4.3 Left-Sided Z-Transform
4.4 Right-Sided Z-Transform
4.5 Two-Sided Z-Transform
4.6 Convergence of the Z-Transform
4.7 System Stability
4.8 Properties of the Z-Transform
4.9 Common Z-Transform Pairs
4.10 Inverse Z-Transform
4.11 Pole and Zero Standard Form Plug-In Equations
4.12 Applications of the Z-Transform
4.13 Summary of Useful Equations
4.14 References
5 Finite Impulse Response Digital Filtering
5.1 Review of Digital FIR Filters
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5.2 Parks-McClellan Method of FIR Filter Design
5.3 PM Implementation of Half Band Filters
5.4 References
6 Multirate Finite Impulse Response Filter Design
6.1 Poly Phase Filter (PPF)
6.2 Half Band Filter
6.3 Cascaded Integrator Comb (CIC) Filter
6.4 References
7 Complex to Real Conversion
7.1 A Typical Digital Signal Processing (DSP) System
7.2 Conversion of a Complex Signal to a Real Signal
7.3 Complex to Real Simulation Results
7.4 Reference
8 Digital Frequency Synthesis
8.1 Numerically Controlled Oscillator (NCO)
8.2 Enhanced NCO Phase Accumulator
8.3 NCO Synthesized Output Frequency Error
8.4 Adding a Programmable Phase Offset to the NCO Output
8.5 Design of an Industry-Grade NCO
8.6 NCO Phase Dither
8.7 References
9 Signal Tuning
9.1 Continuous Time (Analog) Fourier Transform
9.2 Discrete Time (Digital) Fourier Transform
9.3 Useful Equations
9.4 References
10 Elastic Store Memory
10.1 Example Application of an Elastic Store Memory
10.2 PCM Multiplexing Hierarchy
10.3 DS-1C Multiplexer Design Overview
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10.4 Design of the Elastic Store Memory
10.5 Hardware Implementation of the Elastic Store Memory
10.6 Overall DS-1C Multiplexer Design Block Diagram
10.7 Additional Information
10.8 References
11 Digital Data Locked Loops
11.1 Digital Data Locked Design
11.2 Digital Data Locked Steady State Behavior
11.3 Digital Data Locked Transient Behavior
11.4 Data Locked Loop Bit-Level Simulation
11.5 Engineering Note
11.6 Summary of Useful Equations
11.7 References
12 Channelized Filter Bank
12.1 Introductory Description
12.2 Channelizer Functional Overview
12.3 Channelizer Detailed Design Concepts
12.4 Channelizer Software Simulation Results
12.5 Channelizer Hardware Design Example
12.6 Summary of Useful Equations
12.7 References
13 Digital Automatic Gain Control
13.1 Design of a Type I RMS AGC Circuit
13.2 Design of a Type II RMS AGC Circuit
13.3 References
A Mixed Language C/C++ FORTRAN Programming
A.1 Writing a C/C++ Main Program
A.2 Calling Subroutines and Functions from a C/C++ Main
A.3 Writing a FORTRAN Subroutine
A.4 Writing a FORTRAN Function
A.5 Passing Integer Arguments
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A.6 Passing Floating Point Arguments
A.7 Passing Array Arguments
A.8 Passing Pointer Arguments
A.9 Compile/Link Mixed Language C/C++ FORTRAN Programs
A.10 Parks-McClellan FORTRAN Subroutine Called from C Main
A.11 References
Index
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