Discrete Wavelet Transform - D. Sundararajan

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Auteur(s) : D. Sundararajan

Editeur : John Wiley & Sons

Langue : Anglais

Parution : 01/07/2015

Format : Moyen, de 350g à 1kg

Nombre de pages : 344

Expédition : 662

Dimensions : 24.4 x 16.5 x 25.0

ISBN : 1119046068

Résumé :

Provides easy learning and understanding of DWT from a signal processing point of view

• Presents DWT from a digital signal processing point of view, in contrast to the usual mathematical approach, making it highly accessible
• Offers a comprehensive coverage of related topics, including convolution and correlation, Fourier transform, FIR filter, orthogonal and biorthogonal filters
• Organized systematically, starting from the fundamentals of signal processing to the more advanced topics of DWT and Discrete Wavelet Packet Transform.
• Written in a clear and concise manner with abundant examples, figures and detailed explanations
• Features a companion website that has several MATLAB programs for the implementation of the DWT with commonly used filters

This well-written textbook is an introduction to the theory of discrete wavelet transform (DWT) and its applications in digital signal and image processing.
-- Prof. Dr. Manfred Tasche - Institut f?r Mathematik, Uni Rostock

Full review at https://zbmath.org/?q=an:06492561

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Biographie:
Dr. D. Sundararajan, Department Head of Electrical and Electronics Engineering, Adhiyamaan College of Engineering, India.
Dr. Sundararajan obtained his PhD in Electrical Engineering at Concordia University, Montreal, Canada in 1988. As the principle inventor of the latest family of DFT algorithms, he has written three books, three Patents (which have been granted by US, Canada and Britain), and several papers in IEEE Transactions and in the Proceedings of IEEE Conference....

Sommaire:
Preface xi

List of Abbreviations xiii

1 Introduction 1

1.1 The Organization of This Book 2

2 Signals 5

2.1 Signal Classifications 5

2.1.1 Periodic and Aperiodic Signals 5

2.1.2 Even and Odd Signals 6

2.1.3 Energy Signals 7

2.1.4 Causal and Noncausal Signals 9

2.2 Basic Signals 9

2.2.1 Unit-Impulse Signal 9

2.2.2 Unit-Step Signal 10

2.2.3 The Sinusoid 10

2.3 The Sampling Theorem and the Aliasing Effect 12

2.4 Signal Operations 13

2.4.1 Time Shifting 13

2.4.2 Time Reversal 14

2.4.3 Time Scaling 14

2.5 Summary 17

Exercises 17

3 Convolution and Correlation 21

3.1 Convolution 21

3.1.1 The Linear Convolution 21

3.1.2 Properties of Convolution 24

3.1.3 The Periodic Convolution 25

3.1.4 The Border Problem 25

3.1.5 Convolution in the DWT 26

3.2 Correlation 28

3.2.1 The Linear Correlation 28

3.2.2 Correlation and Fourier Analysis 29

3.2.3 Correlation in the DWT 30

3.3 Summary 31

Exercises 31

4 Fourier Analysis of Discrete Signals 37

4.1 Transform Analysis 37

4.2 The Discrete Fourier Transform 38

4.2.1 Parseval's Theorem 43

4.3 The Discrete-Time Fourier Transform 44

4.3.1 Convolution 48

4.3.2 Convolution in the DWT 48

4.3.3 Correlation 50

4.3.4 Correlation in the DWT 50

4.3.5 Time Expansion 52

4.3.6 Sampling Theorem 52

4.3.7 Parseval's Theorem 54

4.4 Approximation of the DTFT 55

4.5 The Fourier Transform 56

4.6 Summary 56

Exercises 57

5 Thez-Transform 59

5.1 The z-Transform 59

5.2 Properties of the z-Transform 60

5.2.1 Linearity 60

5.2.2 Time Shift of a Sequence 61

5.2.3 Convolution 61

5.3 Summary 62

Exercises 62

6 Finite Impulse Response Filters 63

6.1 Characterization 63

6.1.1 Ideal Lowpass Filters 64

6.1.2 Ideal Highpass Filters 65

6.1.3 Ideal Bandpass Filters 66

6.2 Linear Phase Response 66

6.2.1 Even-Symmetric FIR Filters with Odd Number of Coefficients 67

6.2.2 Even-Symmetric FIR Filters with Even Number of Coefficients 68

6.3 Summary 69

Exercises 69

7 Multirate Digital Signal Processing 71

7.1 Decimation 72

7.1.1 Downsampling in the Frequency-Domain 72

7.1.2 Downsampling Followed by Filtering 75

7.2 Interpolation 77

7.2.1 Upsampling in the Frequency-Domain 77

7.2.2 Filtering Followed by Upsampling 78

7.3 Two-Channel Filter Bank 79

7.3.1 Perfect Reconstruction Conditions 81

7.4 Polyphase Form of the Two-Channel Filter Bank 84

7.4.1 Decimation 84

7.4.2 Interpolation 87

7.4.3 Polyphase Form of the Filter Bank 91

7.5 Summary 94

Exercises 94

8 The Haar Discrete Wavelet Transform 97

8.1 Introduction 97

8.1.1 Signal Representation 97

8.1.2 The Wavelet Transform Concept 98

8.1.3 Fourier and Wavelet Transform Analyses 98

8.1.4 Time-Frequency Domain 99

8.2 The Haar Discrete Wavelet Transform 100

8.2.1 The Haar DWT and the 2-Point DFT 102

8.2.2 The Haar Transform Matrix 103

8.3 The Time-Frequency Plane 107

8.4 Wavelets from the Filter Coefficients 111

8.4.1 Two Scale Relations 116

8.5 The 2-D Haar Discrete Wavelet Transform 118

8.6 Discontinuity Detection 126

8.7 Summary 127

Exercises 128

9 Orthogonal Filter Banks 131

9.1 Haar Filter 132

9.2 Daubechies Filter 135

9.3 Orthogonality Condit...