Produktbild: Machine Learning and Big Data

Machine Learning and Big Data Concepts, Algorithms, Tools and Applications

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Beschreibung

Produktdetails

Einband

Gebundene Ausgabe

Erscheinungsdatum

01.09.2020

Herausgeber

Uma N. Dulhare + weitere

Verlag

John Wiley & Sons

Seitenzahl

544

Maße (L/B/H)

22.9/15.2/2.9 cm

Gewicht

875 g

Auflage

1. Auflage

Sprache

Englisch

ISBN

978-1-119-65474-2

Beschreibung

Produktdetails

Einband

Gebundene Ausgabe

Erscheinungsdatum

01.09.2020

Herausgeber

Verlag

John Wiley & Sons

Seitenzahl

544

Maße (L/B/H)

22.9/15.2/2.9 cm

Gewicht

875 g

Auflage

1. Auflage

Sprache

Englisch

ISBN

978-1-119-65474-2

Herstelleradresse

Libri GmbH
Europaallee 1
36244 Bad Hersfeld
DE

Email: gpsr@libri.de

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  • Produktbild: Machine Learning and Big Data
  • Preface xix

    Section 1: Theoretical Fundamentals 1

    1 Mathematical Foundation 3
    Afroz and Basharat Hussain

    1.1 Concept of Linear Algebra 3

    1.1.1 Introduction 3

    1.1.2 Vector Spaces 5

    1.1.3 Linear Combination 6

    1.1.4 Linearly Dependent and Independent Vectors 7

    1.1.5 Linear Span, Basis and Subspace 8

    1.1.6 Linear Transformation (or Linear Map) 9

    1.1.7 Matrix Representation of Linear Transformation 10

    1.1.8 Range and Null Space of Linear Transformation 13

    1.1.9 Invertible Linear Transformation 15

    1.2 Eigenvalues, Eigenvectors, and Eigendecomposition of a Matrix 15

    1.2.1 Characteristics Polynomial 16

    1.2.1.1 Some Results on Eigenvalue 16

    1.2.2 Eigendecomposition 18

    1.3 Introduction to Calculus 20

    1.3.1 Function 20

    1.3.2 Limits of Functions 21

    1.3.2.1 Some Properties of Limits 22

    1.3.2.2 1nfinite Limits 25

    1.3.2.3 Limits at Infinity 26

    1.3.3 Continuous Functions and Discontinuous Functions 26

    1.3.3.1 Discontinuous Functions 27

    1.3.3.2 Properties of Continuous Function 27

    1.3.4 Differentiation 28

    References 29

    2 Theory of Probability 31
    Parvaze Ahmad Dar and Afroz

    2.1 Introduction 31

    2.1.1 Definition 31

    2.1.1.1 Statistical Definition of Probability 31

    2.1.1.2 Mathematical Definition of Probability 32

    2.1.2 Some Basic Terms of Probability 32

    2.1.2.1 Trial and Event 32

    2.1.2.2 Exhaustive Events (Exhaustive Cases) 33

    2.1.2.3 Mutually Exclusive Events 33

    2.1.2.4 Equally Likely Events 33

    2.1.2.5 Certain Event or Sure Event 33

    2.1.2.6 Impossible Event or Null Event (¿) 33

    2.1.2.7 Sample Space 34

    2.1.2.8 Permutation and Combination 34

    2.1.2.9 Examples 35

    2.2 Independence in Probability 38

    2.2.1 Independent Events 38

    2.2.2 Examples: Solve the Following Problems 38

    2.3 Conditional Probability 41

    2.3.1 Definition 41

    2.3.2 Mutually Independent Events 42

    2.3.3 Examples 42

    2.4 Cumulative Distribution Function 43

    2.4.1 Properties 44

    2.4.2 Example 44

    2.5 Baye's Theorem 46

    2.5.1 Theorem 46

    2.5.1.1 Examples 47

    2.6 Multivariate Gaussian Function 50

    2.6.1 Definition 50

    2.6.1.1 Univariate Gaussian (i.e., One Variable Gaussian) 50

    2.6.1.2 Degenerate Univariate Gaussian 51

    2.6.1.3 Multivariate Gaussian 51

    References 51

    3 Correlation and Regression 53
    Mohd. Abdul Haleem Rizwan

    3.1 Introduction 53

    3.2 Correlation 54

    3.2.1 Positive Correlation and Negative Correlation 54

    3.2.2 Simple Correlation and Multiple Correlation 54

    3.2.3 Partial Correlation and Total Correlation 54

    3.2.4 Correlation Coefficient 55

    3.3 Regression 57

    3.3.1 Linear Regression 64

    3.3.2 Logistic Regression 64

    3.3.3 Polynomial Regression 65

    3.3.4 Stepwise Regression 66

    3.3.5 Ridge Regression 67

    3.3.6 Lasso Regression 67

    3.3.7 Elastic Net Regression 68

    3.4 Conclusion 68

    References 69

    Section 2: Big Data and Pattern Recognition 71

    4 Data Preprocess 73
    Md. Sharif Hossen

    4.1 Introduction 73

    4.1.1 Need of Data Preprocessing 74

    4.1.2 Main Tasks in Data Preprocessing 75

    4.2 Data Cleaning 77

    4.2.1 Missing Data 77

    4.2.2 Noisy Data 78

    4.3 Data Integration 80

    4.3.1 ¿2 Correlation Test 82

    4.3.2 Correlation Coe¿cient Test 82

    4.3.3 Covariance Test 83

    4.4 Data Transformation 83

    4.4.1 Normalization 83

    4.4.2 Attribute Selection 85

    4.4.3 Discretization 86

    4.4.4 Concept Hierarchy Generation 86

    4.5 Data Reduction 88

    4.5.1 Data Cube Aggregation 88

    4.5.2 Attribute Subset Selection 90

    4.5.3 Numerosity Reduction 91

    4.5.4 Dimensionality Reduction 95

    4.6 Conclusion 101

    Acknowledgements 101

    References 101

    5 Big Data 105
    R. Chinnaiyan

    5.1 Introduction 105

    5.2 Big Data Evaluation With Its Tools 107

    5.3 Architecture of Big Data 107

    5.3.1 Big Data Analytics Framework Workflow 107

    5.4 Issues and Challenges 109

    5.4.1 Volume 109

    5.4.2 Variety of Data 110

    5.4.3 Velocity 110

    5.5 Big Data Analytics Tools 110

    5.6 Big Data Use Cases 114

    5.6.1 Banking and Finance 114

    5.6.2 Fraud Detection 114

    5.6.3 Customer Division and Personalized Marketing 114

    5.6.4 Customer Support 115

    5.6.5 Risk Management 116

    5.6.6 Life Time Value Prediction 116

    5.6.7 Cyber Security Analytics 117

    5.6.8 Insurance Industry 118

    5.6.9 Health Care Sector 118

    5.6.9.1 Big Data Medical Decision Support 120

    5.6.9.2 Big Data-Based Disorder Management 120

    5.6.9.3 Big Data-Based Patient Monitoring and Control 120

    5.6.9.4 Big Data-Based Human Routine Analytics 120

    5.6.10 Internet of Things 121

    5.6.11 Weather Forecasting 121

    5.7 Where IoT Meets Big Data 122

    5.7.1 IoT Platform 122

    5.7.2 Sensors or Devices 123

    5.7.3 Device Aggregators 123

    5.7.4 IoT Gateway 123

    5.7.5 Big Data Platform and Tools 124

    5.8 Role of Machine Learning For Big Data and IoT 124

    5.8.1 Typical Machine Learning Use Cases 125

    5.9 Conclusion 126

    References 127

    6 Pattern Recognition Concepts 131
    Ambeshwar Kumar, R. Manikandan and C. Thaventhiran

    6.1 Classifier 132

    6.1.1 Introduction 132

    6.1.2 Explanation-Based Learning 133

    6.1.3 Isomorphism and Clique Method 135

    6.1.4 Context-Dependent Classification 138

    6.1.5 Summary 139

    6.2 Feature Processing 140

    6.2.1 Introduction 140

    6.2.2 Detection and Extracting Edge With Boundary Line 141

    6.2.3 Analyzing the Texture 142

    6.2.4 Feature Mapping in Consecutive Moving Frame 143

    6.2.5 Summary 145

    6.3 Clustering 145

    6.3.1 Introduction 145

    6.3.2 Types of Clustering Algorithms 146

    6.3.2.1 Dynamic Clustering Method 148

    6.3.2.2 Model-Based Clustering 148

    6.3.3 Application 149

    6.3.4 Summary 150

    6.4 Conclusion 151

    References 151

    Section 3: Machine Learning: Algorithms & Applications 153

    7 Machine Learning 155
    Elham Ghanbari and Sara Najafzadeh

    7.1 History and Purpose of Machine Learning 155

    7.1.1 History of Machine Learning 155

    7.1.1.1 What is Machine Learning? 156

    7.1.1.2 When the Machine Learning is Needed? 157

    7.1.2 Goals and Achievements in Machine Learning 158

    7.1.3 Applications of Machine Learning 158

    7.1.3.1 Practical Machine Learning Examples 159

    7.1.4 Relation to Other Fields 161

    7.1.4.1 Data Mining 161

    7.1.4.2 Artificial Intelligence 162

    7.1.4.3 Computational Statistics 162

    7.1.4.4 Probability 163

    7.1.5 Limitations of Machine Learning 163

    7.2 Concept of Well-Defined Learning Problem 164

    7.2.1 Concept Learning 164

    7.2.1.1 Concept Representation 166

    7.2.1.2 Instance Representation 167

    7.2.1.3 The Inductive Learning Hypothesis 167

    7.2.2 Concept Learning as Search 167

    7.2.2.1 Concept Generality 168

    7.3 General-to-Specific Ordering Over Hypotheses 169

    7.3.1 Basic Concepts: Hypothesis, Generality 169

    7.3.2 Structure of the Hypothesis Space 169

    7.3.2.1 Hypothesis Notations 169

    7.3.2.2 Hypothesis Evaluations 170

    7.3.3 Ordering on Hypotheses: General to Specific 170

    7.3.3.1 Most Specific Generalized 171

    7.3.3.2 Most General Specialized 173

    7.3.3.3 Generalization and Specialization Operators 173

    7.3.4 Hypothesis Space Search by Find-S Algorithm 174

    7.3.4.1 Properties of the Find-S Algorithm 176

    7.3.4.2 Limitations of the Find-S Algorithm 176

    7.4 Version Spaces and Candidate Elimination Algorithm 177

    7.4.1 Representing Version Spaces 177

    7.4.1.1 General Boundary 178

    7.4.1.2 Specific Boundary 178

    7.4.2 Version Space as Search Strategy 179

    7.4.3 The List-Eliminate Method 179

    7.4.4 The Candidate-Elimination Method 180

    7.4.4.1 Example 181

    7.4.4.2 Convergence of Candidate-Elimination Method 183

    7.4.4.3 Inductive Bias for Candidate-Elimination 184

    7.5 Concepts of Machine Learning Algorithm 185

    7.5.1 Types of Learning Algorithms 185

    7.5.1.1 Incremental vs. Batch Learning Algorithms 186

    7.5.1.2 Offline vs. Online Learning Algorithms 188

    7.5.1.3 Inductive vs. Deductive Learning Algorithms 189

    7.5.2 A Framework for Machine Learning Algorithms 189

    7.5.2.1 Training Data 190

    7.5.2.2 Target Function 190

    7.5.2.3 Construction Model 191

    7.5.2.4 Evaluation 191

    7.5.3 Types of Machine Learning Algorithms 194

    7.5.3.1 Supervised Learning 196

    7.5.3.2 Unsupervised Learning 198

    7.5.3.3 Semi Supervised Learning 200

    7.5.3.4 Reinforcement Learning 200

    7.5.3.5 Deep Learning 202

    7.5.4 Types of Machine Learning Problems 203

    7.5.4.1 Classification 204

    7.5.4.2 Clustering 204

    7.5.4.3 Optimization 205

    7.5.4.4 Regression 205

    Conclusion 205

    References 206

    8 Performance of Supervised Learning Algorithms on Multi-Variate Datasets 209
    Asif Iqbal Hajamydeen and Rabab Alayham Abbas Helmi

    8.1 Introduction 209

    8.2 Supervised Learning Algorithms 210

    8.2.1 Datasets and Experimental Setup 211

    8.2.2 Data Treatment/Preprocessing 212

    8.3 Classification 212

    8.3.1 Support Vector Machines (SVM) 213

    8.3.2 Naive Bayes (NB) Algorithm 214

    8.3.3 Bayesian Network (BN) 214

    8.3.4 Hidden Markov Model (HMM) 215

    8.3.5 K-Nearest Neighbour (KNN) 216

    8.3.6 Training Time 216

    8.4 Neural Network 217

    8.4.1 Artificial Neural Networks Architecture 219

    8.4.2 Application Areas 222

    8.4.3 Artificial Neural Networks and Time Series 224

    8.5 Comparisons and Discussions 225

    8.5.1 Comparison of Classification Accuracy 225

    8.5.2 Forecasting Efficiency Comparison 226

    8.5.3 Recurrent Neural Network (RNN) 226

    8.5.4 Backpropagation Neural Network (BPNN) 228

    8.5.5 General Regression Neural Network 229

    8.6 Summary and Conclusion 230

    References 231

    9 Unsupervised Learning 233
    M. Kumara Swamy and Tejaswi Puligilla

    9.1 Introduction 233

    9.2 Related Work 234

    9.3 Unsupervised Learning Algorithms 235

    9.4 Classification of Unsupervised Learning Algorithms 238

    9.4.1 Hierarchical Methods 238

    9.4.2 Partitioning Methods 239

    9.4.3 Density-Based Methods 242

    9.4.4 Grid-Based Methods 245

    9.4.5 Constraint-Based Clustering 245

    9.5 Unsupervised Learning Algorithms in ML 246

    9.5.1 Parametric Algorithms 246

    9.5.2 Non-Parametric Algorithms 246

    9.5.3 Dirichlet Process Mixture Model 247

    9.5.4 X-Means 248

    9.6 Summary and Conclusions 248

    References 248

    10 Semi-Supervised Learning 251
    Manish Devgan, Gaurav Malik and Deepak Kumar Sharma

    10.1 Introduction 252

    10.1.1 Semi-Supervised Learning 252

    10.1.2 Comparison With Other Paradigms 255

    10.2 Training Models 257

    10.2.1 Self-Training 257

    10.2.2 Co-Training 259

    10.3 Generative Models-Introduction 261

    10.3.1 Image Classification 264

    10.3.2 Text Categorization 266

    10.3.3 Speech Recognition 268

    10.3.4 Baum-Welch Algorithm 268

    10.4 S3VMs 270

    10.5 Graph-Based Algorithms 274

    10.5.1 Mincut 275

    10.5.2 Harmonic 276

    10.5.3 Manifold Regularization 277

    10.6 Multiview Learning 277

    10.7 Conclusion 278

    References 279

    11 Reinforcement Learning 281
    Amandeep Singh Bhatia, Mandeep Kaur Saggi, Amit Sundas and Jatinder Ashta

    11.1 Introduction: Reinforcement Learning 281

    11.1.1 Elements of Reinforcement Learning 283

    11.2 Model-Free RL 284

    11.2.1 Q-Learning 285

    11.2.2 R-Learning 286

    11.3 Model-Based RL 287

    11.3.1 SARSA Learning 289

    11.3.2 Dyna-Q Learning 290

    11.3.3 Temporal Difference 291

    11.3.3.1 TD(0) Algorithm 292

    11.3.3.2 TD(1) Algorithm 293

    11.3.3.3 TD(¿) Algorithm 294

    11.3.4 Monte Carlo Method 294

    11.3.4.1 Monte Carlo Reinforcement Learning 296

    11.3.4.2 Monte Carlo Policy Evaluation 296

    11.3.4.3 Monte Carlo Policy Improvement 298

    11.4 Conclusion 298

    References 299

    12 Application of Big Data and Machine Learning 305
    Neha Sharma, Sunil Kumar Gautam, Azriel A. Henry and Abhimanyu Kumar

    12.1 Introduction 306

    12.2 Motivation 307

    12.3 Related Work 308

    12.4 Application of Big Data and ML 309

    12.4.1 Healthcare 309

    12.4.2 Banking and Insurance 312

    12.4.3 Transportation 314

    12.4.4 Media and Entertainment 316

    12.4.5 Education 317

    12.4.6 Ecosystem Conservation 319

    12.4.7 Manufacturing 321

    12.4.8 Agriculture 322

    12.5 Issues and Challenges 324

    12.6 Conclusion 326

    References 326

    Section 4: Machine Learning's Next Frontier 335

    13 Transfer Learning 337
    Riyanshi Gupta, Kartik Krishna Bhardwaj and Deepak Kumar Sharma

    13.1 Introduction 338

    13.1.1 Motivation, Definition, and Representation 338

    13.2 Traditional Learning vs. Transfer Learning 338

    13.3 Key Takeaways: Functionality 340

    13.4 Transfer Learning Methodologies 341

    13.5 Inductive Transfer Learning 342

    13.6 Unsupervised Transfer Learning 344

    13.7 Transductive Transfer Learning 346

    13.8 Categories in Transfer Learning 347

    13.9 Instance Transfer 348

    13.10 Feature Representation Transfer 349

    13.11 Parameter Transfer 349

    13.12 Relational Knowledge Transfer 350

    13.13 Relationship With Deep Learning 351

    13.13.1 Transfer Learning in Deep Learning 351

    13.13.2 Types of Deep Transfer Learning 352

    13.13.3 Adaptation of Domain 352

    13.13.4 Domain Confusion 353

    13.13.5 Multitask Learning 354

    13.13.6 One-Shot Learning 354

    13.13.7 Zero-Shot Learning 355

    13.14 Applications: Allied Classical Problems 355

    13.14.1 Transfer Learning for Natural Language Processing 356

    13.14.2 Transfer Learning for Computer Vision 356

    13.14.3 Transfer Learning for Audio and Speech 357

    13.15 Further Advancements and Conclusion 357

    References 358

    Section 5: Hands-On and Case Study 361

    14 Hands on MAHOUT-Machine Learning Tool
    Uma N. Dulhare and Sheikh Gouse

    14.1 Introduction to Mahout 363

    14.1.1 Features 366

    14.1.2 Advantages 366

    14.1.3 Disadvantages 366

    14.1.4 Application 366

    14.2 Installation Steps of Apache Mahout Using Cloudera 367

    14.2.1 Installation of VMware Workstation 367

    14.2.2 Installation of Cloudera 368

    14.2.3 Installation of Mahout 383

    14.2.4 Installation of Maven 384

    14.2.5 Testing Mahout 386

    14.3 Installation Steps of Apache Mahout Using Windows 10 386

    14.3.1 Installation of Java 386

    14.3.2 Installation of Hadoop 387

    14.3.3 Installation of Mahout 387

    14.3.4 Installation of Maven 387

    14.3.5 Path Setting 388

    14.3.6 Hadoop Configuration 391

    14.4 Installation Steps of Apache Mahout Using Eclipse 395

    14.4.1 Eclipse Installation 395

    14.4.2 Installation of Maven Through Eclipse 396

    14.4.3 Maven Setup for Mahout Configuration 399

    14.4.4 Building the Path- 402

    14.4.5 Modifying the pom.xml File 405

    14.4.6 Creating the Data File 407

    14.4.7 Adding External Jar Files 408

    14.4.8 Creating the New Package and Classes 410

    14.4.9 Result 411

    14.5 Mahout Algorithms 412

    14.5.1 Classification 412

    14.5.2 Clustering 413

    14.5.3 Recommendation 415

    14.6 Conclusion 418

    References 418

    15 Hands-On H2O Machine Learning Tool 423
    Uma N. Dulhare, Azmath Mubeen and Khaleel Ahmed

    15.1 Introduction 424

    15.2 Installation 425

    15.2.1 The Process of Installation 425

    15.3 Interfaces 431

    15.4 Programming Fundamentals 432

    15.4.1 Data Manipulation 432

    15.4.1.1 Data Types 432

    15.4.1.2 Data Import 435

    15.4.2 Models 436

    15.4.2.1 Model Training 436

    15.4.3 Discovering Aspects 437

    15.4.3.1 Converting Data Frames 437

    15.4.4 H2O Cluster Actions 438

    15.4.4.1 H2O Key Value Retrieval 438

    15.4.4.2 H2O Cluster Connection 438

    15.4.5 Commands 439

    15.4.5.1 Cluster Information 439

    15.4.5.2 General Data Operations 441

    15.4.5.3 String Manipulation Commands 442

    15.5 Machine Learning in H2O 442

    15.5.1 Supervised Learning 442

    15.5.2 Unsupervised Learning 443

    15.6 Applications of H2O 443

    15.6.1 Deep Learning 443

    15.6.2 K-Fold Cross-Authentication or Validation 448

    15.6.3 Stacked Ensemble and Random Forest Estimator 450

    15.7 Conclusion 452

    References 453

    16 Case Study: Intrusion Detection System Using Machine Learning 455
    Syeda Hajra Mahin, Fahmina Taranum and Reshma Nikhat

    16.1 Introduction 456

    16.1.1 Components Used to Design the Scenario Include 456

    16.1.1.1 Black Hole 456

    16.1.1.2 Intrusion Detection System 457

    16.1.1.3 Components Used From MATLAB Simulator 458

    16.2 System Design 465

    16.2.1 Three Sub-Network Architecture 465

    16.2.2 Using Classifiers of MATLAB 465

    16.3 Existing Proposals 467

    16.4 Approaches Used in Designing the Scenario 469

    16.4.1 Algorithm Used in QualNet 469

    16.4.2 Algorithm Applied in MATLAB 471

    16.5 Result Analysis 471

    16.5.1 Results From QualNet 471

    16.5.1.1 Deployment 471

    16.5.1.2 Detection 472

    16.5.1.3 Avoidance 473

    16.5.1.4 Validation of Conclusion 473

    16.5.2 Applying Results to MATLAB 473

    16.5.2.1 K-Nearest Neighbor 475

    16.5.2.2 SVM 477

    16.5.2.3 Decision Tree 477

    16.5.2.4 Naive Bayes 479

    16.5.2.5 Neural Network 479

    16.6 Conclusion 484

    References 484

    17 Inclusion of Security Features for Implications of Electronic Governance Activities 487
    Prabal Pratap and Nripendra Dwivedi

    17.1 Introduction 487

    17.2 Objective of E-Governance 491

    17.3 Role of Identity in E-Governance 493

    17.3.1 Identity 493

    17.3.2 Identity Management and its Buoyancy Against Identity Theft in E-Governance 494

    17.4 Status of E-Governance in Other Countries 496

    17.4.1 E-Governance Services in Other Countries Like Australia and South Africa 496

    17.4.2 Adaptation of Processes and Methodology for Developing Countries 496

    17.4.3 Different Programs Related to E-Governance 499

    17.5 Pros and Cons of E-Governance 501

    17.6 Challenges of E-Governance in Machine Learning 502

    17.7 Conclusion 503

    References 503

    Index 505