Audio source separation and speech enhancement / edited by Emmanuel Vincent, Tuomas Virtanen, Sharon Gannot.
Contributor(s): Vincent, Emmanuel (Research scientist) [editor.] | Virtanen, Tuomas [editor.] | Gannot, Sharon [editor.]
Language: English Publisher: Hoboken, NJ : John Wiley & Sons, 2018Description: 1 online resourceContent type: text Media type: computer Carrier type: online resourceISBN: 9781119279914 (epub); 9781119279884 (pdf)Subject(s): Speech processing systems | Automatic speech recognitionGenre/Form: Electronic books.DDC classification: 006.4/54 LOC classification: TK7882.S65Online resources: Full text available at Wiley Online Library Click here to viewItem type | Current location | Home library | Call number | Status | Date due | Barcode | Item holds |
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EBOOK | COLLEGE LIBRARY | COLLEGE LIBRARY | 006.454 Au251 2018 (Browse shelf) | Available | 50410 |
ABOUT THE AUTHOR
EMMANUEL VINCENT is a Senior Research Scientist with Inria, Nancy, France. His research focuses on machine learning for speech and audio signal processing. He has been working on audio source separation for 15 years and co-authored over 180 publications in this field. His contributions include harmonic nonnegative matrix factorization, full-rank spatial covariance modeling, joint spatial/spectral estimation, deep learning based multichannel source separation, and objective performance metrics. He has given several keynotes, tutorials and summer school lectures, including at Interspeech 2012 and 2016, WASPAA 2015 and LVA/ICA 2015. He is a founding chair of the series of Signal Separation Evaluation Campaigns (SiSEC) and CHiME Speech Separation and Recognition Challenges and the chair of ISCA's special interest group on Robust Speech Processing.
TUOMAS VIRTANEN is a Professor with the Laboratory of Signal Processing, Tampere University of Technology, Finland, where he is leading the Audio Research Group. He is known for his pioneering work on single-channel sound source separation using nonnegative matrix factorization, and its application to noise-robust speech recognition, music content analysis, and sound event detection. His research interests also include content analysis and processing of audio signals in general. He has authored more than 170 publications and received four best paper awards. He is an IEEE Senior Member, a member of the Audio and Acoustic Signal Processing Technical Committee of IEEE Signal Processing Society, Associate Editor of IEEE/ACM Transaction on Audio, Speech, and Language Processing, and recipient of the ERC 2014 Starting Grant.
SHARON GANNOT is a Full Professor at the Faculty of Engineering, Bar-Ilan University, Israel, where he is heading the Speech and Signal Processing laboratory and the Signal Processing Track. His research interests include multi-microphone speech processing; distributed algorithms for noise reduction and speaker separation; array processing on manifold; dereverberation; single-microphone speech enhancement; and speaker localization and tracking. He received the Bar-Ilan University's Outstanding Lecturer Award for 2010 and 2014 and the Bar-Ilan Rector Innovation in Research Award in 2018. He has co-authored over 200 publications and lectured tutorials at ICASSP 2012, EUSIPCO 2012, ICASSP 2013, and EUSIPCO 2013 and a keynote address at IWAENC 2012. He was a co-editor of the book Speech Processing in Modern Communication: Challenges and Perspectives (Springer, 2012). He also served as an Associate Editor and a Senior Area Chair of the IEEE Transactions on Speech, Audio and Language Processing. He currently serves as the Chair of the IEEE Audio and Acoustic Signal Processing (AASP) Technical Committee.
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Includes bibliographical references and index.
List of Authors xvii
Preface xxi
Acknowledgment xxiii
Notations xxv
Acronyms xxix
About the Companion Website xxxi
Part I Prerequisites 1
1 Introduction 3
Emmanuel Vincent, Sharon Gannot, and Tuomas Virtanen
1.1 Why are Source Separation and Speech Enhancement Needed? 3
1.2 What are the Goals of Source Separation and Speech Enhancement? 4
1.3 How can Source Separation and Speech Enhancement be Addressed? 9
1.4 Outline 11
Bibliography 12
2 Time-Frequency Processing: Spectral Properties 15
Tuomas Virtanen, Emmanuel Vincent, and Sharon Gannot
2.1 Time-Frequency Analysis and Synthesis 15
2.2 Source Properties in the Time-Frequency Domain 23
2.3 Filtering in the Time-Frequency Domain 25
2.4 Summary 28
Bibliography 28
3 Acoustics: Spatial Properties 31
Emmanuel Vincent, Sharon Gannot, and Tuomas Virtanen
3.1 Formalization of the Mixing Process 31
3.2 Microphone Recordings 32
3.3 Artificial Mixtures 36
3.4 Impulse Response Models 37
3.5 Summary 43
Bibliography 43
4 Multichannel Source Activity Detection, Localization, and Tracking 47
Pasi Pertilä, Alessio Brutti, Piergiorgio Svaizer, and Maurizio Omologo
4.1 Basic Notions in Multichannel Spatial Audio 47
4.2 Multi-Microphone Source Activity Detection 52
4.3 Source Localization 54
4.4 Summary 60
Bibliography 60
Part II Single-Channel Separation and Enhancement 65
5 Spectral Masking and Filtering 67
Timo Gerkmann and Emmanuel Vincent
5.1 Time-Frequency Masking 67
5.2 Mask Estimation Given the Signal Statistics 70
5.3 Perceptual Improvements 81
5.4 Summary 82
Bibliography 83
6 Single-Channel Speech Presence Probability Estimation and Noise Tracking 87
Rainer Martin and Israel Cohen
6.1 Speech Presence Probability and its Estimation 87
6.2 Noise Power Spectrum Tracking 93
6.3 Evaluation Measures 102
6.4 Summary 104
Bibliography 104
7 Single-Channel Classification and Clustering Approaches 107
FelixWeninger, Jun Du, Erik Marchi, and Tian Gao
7.1 Source Separation by Computational Auditory Scene Analysis 108
7.2 Source Separation by Factorial HMMs 111
7.3 Separation Based Training 113
7.4 Summary 125
Bibliography 125
8 Nonnegative Matrix Factorization 131
Roland Badeau and Tuomas Virtanen
8.1 NMF and Source Separation 131
8.2 NMF Theory and Algorithms 137
8.3 NMF Dictionary LearningMethods 145
8.4 Advanced NMF Models 148
8.5 Summary 156
Bibliography 156
9 Temporal Extensions of Nonnegative Matrix Factorization 161
Cédric Févotte, Paris Smaragdis, NasserMohammadiha, and Gautham J.Mysore
9.1 Convolutive NMF 161
9.2 Overview of DynamicalModels 169
9.3 Smooth NMF 170
9.4 Nonnegative State-Space Models 174
9.5 Discrete DynamicalModels 178
9.6 The Use of DynamicModels in Source Separation 182
9.7 Which Model to Use? 183
9.8 Summary 184
9.9 Standard Distributions 184
Bibliography 185
Part III Multichannel Separation and Enhancement 189
10 Spatial Filtering 191
Shmulik Markovich-Golan,Walter Kellermann, and Sharon Gannot
10.1 Fundamentals of Array Processing 192
10.2 Array Topologies 197
10.3 Data-Independent Beamforming 199
10.4 Data-Dependent Spatial Filters: Design Criteria 202
10.5 Generalized Sidelobe Canceler Implementation 209
10.6 Postfilters 210
10.7 Summary 211
Bibliography 212
11 Multichannel Parameter Estimation 219
Shmulik Markovich-Golan,Walter Kellermann, and Sharon Gannot
11.1 Multichannel Speech Presence Probability Estimators 219
11.2 Covariance Matrix Estimators Exploiting SPP 227
11.3 Methods forWeakly Guided and Strongly Guided RTF Estimation 228
11.4 Summary 231
Bibliography 231
12 Multichannel Clustering and Classification Approaches 235
Michael I.Mandel, Shoko Araki, and Tomohiro Nakatani
12.1 Two-Channel Clustering 236
12.2 Multichannel Clustering 244
12.3 Multichannel Classification 251
12.4 Spatial Filtering Based on Masks 255
12.5 Summary 257
Bibliography 258
13 Independent Component and Vector Analysis 263
Hiroshi Sawada and Zbynˇek Koldovský
13.1 Convolutive Mixtures and their Time-Frequency Representations 264
13.2 Frequency-Domain Independent Component Analysis 265
13.3 Independent Vector Analysis 279
13.4 Example 280
13.5 Summary 284
Bibliography 284
14 Gaussian Model Based Multichannel Separation 289
Alexey Ozerov and Hirokazu Kameoka
14.1 Gaussian Modeling 289
14.2 Library of Spectral and SpatialModels 295
14.3 Parameter Estimation Criteria and Algorithms 300
14.4 Detailed Presentation of Some Methods 305
14.5 Summary 312
Acknowledgment 312
Bibliography 312
15 Dereverberation 317
Emanuël A.P. Habets and Patrick A. Naylor
15.1 Introduction to Dereverberation 317
15.2 Reverberation Cancellation Approaches 319
15.3 Reverberation Suppression Approaches 329
15.4 Direct Estimation 335
15.5 Evaluation of Dereverberation 336
15.6 Summary 337
Bibliography 337
Part IV Application Scenarios and Perspectives 345
16 Applying Source Separation to Music 347
Bryan Pardo, Antoine Liutkus, Zhiyao Duan, and Gaël Richard
16.1 Challenges and Opportunities 348
16.2 Nonnegative Matrix Factorization in the Case of Music 349
16.3 Taking Advantage of the Harmonic Structure of Music 354
16.4 Nonparametric Local Models: Taking Advantage of Redundancies in Music 358
16.5 Taking Advantage of Multiple Instances 363
16.6 Interactive Source Separation 367
16.7 Crowd-Based Evaluation 367
16.8 Some Examples of Applications 368
16.9 Summary 370
Bibliography 370
17 Application of Source Separation to Robust Speech Analysis and Recognition 377
ShinjiWatanabe, Tuomas Virtanen, and Dorothea Kolossa
17.1 Challenges and Opportunities 377
17.2 Applications 380
17.3 Robust Speech Analysis and Recognition 390
17.4 Integration of Front-End and Back-End 397
17.5 Use of Multimodal Information with Source Separation 403
17.6 Summary 404
Bibliography 405
18 Binaural Speech Processing with Application to Hearing Devices 413
Simon Doclo, Sharon Gannot, Daniel Marquardt, and Elior Hadad
18.1 Introduction to Binaural Processing 413
18.2 Binaural Hearing 415
18.3 Binaural Noise Reduction Paradigms 416
18.4 The Binaural Noise Reduction Problem 420
18.5 Extensions for Diffuse Noise 425
18.6 Extensions for Interfering Sources 431
18.7 Summary 437
Bibliography 437
19 Perspectives 443
Emmanuel Vincent, Tuomas Virtanen, and Sharon Gannot
19.1 Advancing Deep Learning 443
19.2 Exploiting Phase Relationships 447
19.3 AdvancingMultichannel Processing 450
19.4 Addressing Multiple-Device Scenarios 453
19.5 TowardsWidespread Commercial Use 455
Acknowledgment 457
Bibliography 457
Index 465
Learn the technology behind hearing aids, Siri, and Echo
Audio source separation and speech enhancement aim to extract one or more source signals of interest from an audio recording involving several sound sources. These technologies are among the most studied in audio signal processing today and bear a critical role in the success of hearing aids, hands-free phones, voice command and other noise-robust audio analysis systems, and music post-production software.
Research on this topic has followed three convergent paths, starting with sensor array processing, computational auditory scene analysis, and machine learning based approaches such as independent component analysis, respectively. This book is the first one to provide a comprehensive overview by presenting the common foundations and the differences between these techniques in a unified setting.
Key features:
Consolidated perspective on audio source separation and speech enhancement.
Both historical perspective and latest advances in the field, e.g. deep neural networks.
Diverse disciplines: array processing, machine learning, and statistical signal processing.
Covers the most important techniques for both single-channel and multichannel processing.
This book provides both introductory and advanced material suitable for people with basic knowledge of signal processing and machine learning. Thanks to its comprehensiveness, it will help students select a promising research track, researchers leverage the acquired cross-domain knowledge to design improved techniques, and engineers and developers choose the right technology for their target application scenario. It will also be useful for practitioners from other fields (e.g., acoustics, multimedia, phonetics, and musicology) willing to exploit audio source separation or speech enhancement as pre-processing tools for their own needs.
000-099 006
Description based on print version record and CIP data provided by publisher.
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