IoT for Smart Grid

About the Editors xxvii

List of Contributors xxxi

1 Introduction to the Internet of Things 1

Anbazhagan Lavanya, Jayachandran Divya Navamani, and Rahiman Zahira

1.1 Introduction 1

1.2 Evolution of IoT 2

1.3 Need for IoT 3

1.4 Energy Management 4

1.5 Main Components Used in IoT 5

1.6 IoT Devices 6

1.7 IoT Characteristics 7

1.8 IoT Market Share 11

1.9 Conclusion 14

References 15

2 IoT Fundamentals: Platforms, Architectures, and Sensor Technologies 17

Naseer Ahamed Javed, Yogesh Rajkumar, and Kallankurichy P. Kaliyamurthie

2.1 Introduction 17

2.2 Overview of IoT System Architectures and Design Principles 17

2.3 Exploring IoT/M2M Systems and Their Role in Connectivity 23

2.4 Introduction to Sensors and Transducers in IoT 25

2.5 LoWPAN Network Management Protocol (LNMP) 27

2.6 WSN Diagnostic Tools: Ensuring Reliability and Performance 29

2.7 Overview of IoT Communication Technologies 31

2.8 Practical Applications of IoT Platforms, Sensor Technologies and Communication Protocols 34

References 40

3 Communication Protocols for Transactive IoT 43
A. Kamalasegaran, G. Kabilan, and P. Sriramalakshmi

3.1 Introduction 43

3.2 Transactive Systems in Smart Grids 43

3.3 MQTT, CoAP, and Other Protocols in Transactive Systems 45

3.4 Data Distribution Service (DDS) 49

3.5 Edge Computing and Real-Time Implementation 50

3.6 Reliability and Scalability 54

3.7 Case Studies and Real-Life Implementations 57

3.8 Conclusion 58

References 59

4 Transactive IoT: Merging Transactions and Connectivity 63
Burhan Khan, Aabid A. Mir, Naser S. Almutairi, and Khang W. Goh

4.1 Introduction 63

4.2 IoT Integration with Transactive Models 64

4.3 Transactive IoT in Modern Applications 66

4.4 Economic and Market-Based Approaches 71

4.5 Transactive IoT System Architecture 73

4.6 Challenges and Solutions 78

4.7 Conclusion 81

References 82

5 IoT Devices in Transactive System 87
G. Jagadish and P. Sriramalakshmi

5.1 Introduction 87

5.2 Integration of IoT Devices for Data Collection 88

5.3 Role of Sensor 90

5.4 Sensor Types 91

5.5 Role of Sensors During Data Collection 92

5.6 Role of Actuators 93

5.7 Challenges Faced in Device Connectivity 95

5.8 Challenges in Data Security 96

5.9 Conclusion 101

References 101

6 IoT in Power Electronics: Transforming the Future of Energy Management 107
Dhandapani Lakshmi, Rahiman Zahira, Vallikanu Pramila, Gunasekaran Ezhilarasi, Rajesh K. Padmashini, Palanisamy Sivaraman, and Chenniappan Sharmeela

6.1 Introduction to IoT in Power Electronics 107

6.2 IoT in Power Conversion: Enhancing Efficiency and Reliability 112

6.3 Introduction to IIoT-Driven Automation 115

6.4 Future Prospects of IoT in Power Conversion 116

6.5 Regulatory and Standardization Considerations 119

6.6 IoT in Power Transmission for Long Distance 119

6.7 Conclusion 123

References 124

7 Harnessing IoT: Transforming Smart Grid Advancements 127
Pijush K. Dutta Pramanik, Bijoy K. Upadhyaya, Ajay Kushwaha, and Debashish Bhowmik

7.1 Introduction to Smart Grid and IoT Integration 127

7.2 Architecture of a Smart Grid IoT System 131

7.3 Remote Control and Automation in Smart Grids 137

7.4 Automated Load Shifting Strategies Using IoT 141

7.5 IoT Applications for Real-Time Monitoring of Smart Grids 142

7.6 Challenges in Implementing IoT in Smart Grids 151

7.7 Economics of IoT-Enabled Smart Grid 154

7.8 Smart Grid in India 167

7.9 Conclusions 169

References 170

8 Cybersecurity Challenges in Smart Grid IoT 175
Zain Buksh, Neeraj A. Sharma, Rishal Chand, Jashnil Kumar, and A. B. M. Shawkat Ali

8.1 Introduction 175

8.2 Research Background 178

8.3 Cybersecurity Challenges in Smart Grid IoT 183

8.4 Case Studies and Real-World Examples 194

8.5 Future Trends and Considerations 200

8.6 Conclusions 201

References 202

9 IoT-Based Monitoring for Substations 207
Rajesh K. Padmashini, Dhandapani Lakshmi, Rajasekharan Rajasree, Janarthanan N. Rajesh Kumar, Rahiman Zahira, Palanisamy Sivaraman, and Chenniappan Sharmeela

9.1 Introduction to IoT-Based Monitoring for Substations 207

9.2 Components of Substation Automation and Monitoring 208

9.3 Architecture of Substation Automation 209

9.4 The Need for IoT in Substation Monitoring 210

9.5 Automation and Control in Substation Environment 211

9.6 Substation Automation and Monitoring 213

9.7 Examples 215

9.8 Others 217

9.9 Conclusion 218

References 218

10 IoT Application in Condition Monitoring and Fault Diagnosis in Electrical Systems 221
Ravichandran Karthick Manoj, Dhandapani Lakshmi, Rajasekharan Rajasree, Sukumaran Aasha Nandhini, Palanisamy Sivaraman, and Rahiman Zahira

10.1 Introduction 221

10.2 Importance of Condition Monitoring (CM) in Electrical Systems 222

10.3 Enhancing Reliability and Performance of Condition Monitoring 223

10.4 Proactive Maintenance Strategies Enabled by Condition Monitoring 223

10.5 Methods of Condition Monitoring 224

10.6 Implementation of Vibration Analysis 225

10.7 Vibration 226

10.8 What Can Vibration Analysis Detect? 229

10.9 Block Diagram of Vibration Monitoring System 231

10.10 Industrial Applications of Vibration Analysis 232

10.11 Advantages of Vibration Analysis for Condition Monitoring in Electrical Systems 234

10.12 Disadvantages of Vibration Analysis for Condition Monitoring in Electrical Systems 234

10.13 Importance of Fault Diagnosis in Electrical System 235

10.14 Integration with IoT of Conditional Monitoring Electrical System 236

10.15 Real-Time Monitoring and Predictive Maintenance 237

10.16 Energy Management and Asset Performance Optimization 238

10.17 Safety, Compliance, and Future Trends 239

10.18 Future Trends in IoT Application in Condition Monitoring and Fault Diagnosis in Electrical Systems 239

References 240

11 IoT-Powered Robust Anomaly Detection and CNN-Enabled Predictive Maintenance to Enhance Solar PV System Performance 243
Kumaresa P. Punitha

11.1 Introduction 243

11.2 IoT Application in Condition Monitoring 244

11.3 IoT Application in Fault Prediction 245

11.4 Overview of Solar PV System Faults 245

11.5 Need for IoT and CNN Algorithm for Anomaly Detection of Solar PV System 247

11.6 System Description 248

11.7 Proposed Algorithm 248

11.8 Results and Discussion 249

11.9 Conclusion 254

References 254

12 Advancements in Smart Energy Management: Enhancing Efficiency Through Advanced Metering Infrastructure and Energy Monitoring 257
S. Nazrin Salma, A. Niyas Ahamed, and G. Srinivasan

12.1 Introduction to Smart Energy Management 257

12.2 Evolution of Energy Management Systems 258

12.3 Traditional Energy Management 258

12.4 Transition to Smart Grids 259

12.5 Role of Smart Meters and Advanced Metering Infrastructure 260

12.6 Effects on Contemporary Energy Systems 260

12.7 Digital Innovations in Energy Management 260

12.8 Smart Meters: Empowering Consumers 263

12.9 Revolutionizing Energy Consumption 263

12.10 Advanced Metering Infrastructure (AMI): Streamlining Energy 264

12.11 Case Studies of Successful AMI Implementations 264

12.12 Energy Monitoring and Management 265

12.13 Examples of Energy Management Practices 266

12.14 Illustrations and Case Studies in the Practical Application of Smart Energy Management 266

12.15 Optimization of Urban Grids and IoT Devices 266

12.16 Challenges and Opportunities in Smart Energy 267

12.17 Opportunities for Advancements 268

12.18 Real-Time Optimization 268

12.19 Automated Decision-Making 268

12.20 Enhancing Efficiency and Reliability 269

12.21 Real-Time Optimization of Storage Solutions 269

12.22 Managing Variability and Intermittency 269

12.23 Grid Resilience and Stability 270

12.24 Insights into Potential Vulnerabilities 270

12.25 Automation of Grid Operations 270

12.26 Regulatory Frameworks and Policies 271

12.27 Conclusion: The Future of Smart Energy Management 271

References 272

13 IoT for Power Quality Applications 275
Rahiman Zahira, Dhandapani Lakshmi, Shanmugasundaram Logeshkumar, Palanisamy Sivaraman, Chenniappan Sharmeela, and Sanjeevikumar Padmanaban

13.1 Introduction to Power Quality in Modern Electrical Systems 275

13.2 Power Quality Standards 276

13.3 Power Quality Solutions 277

13.4 IOT for Power Quality 280

13.5 The Role of IoT in Enhancing Power Quality 281

13.6 Architecture for Power Quality Management Using IoT 282

13.7 IoT Architecture for Smart Grid and Power Quality Applications 283

13.8 IoT Sensors and Devices for Power Quality Monitoring 286

13.9 Conclusions 287

References 288

14 An IoT and 1D Convolutional Neural Network-Based Method for Smart Building Energy Management 291
Aleena Swetapadma, Nalini P. Behera, Harsh Saran, and Saurav Kumar

14.1 Introduction 291

14.2 One-Dimensional Convolutional Neural Network 292

14.3 Proposed Method 292

14.4 Result 296

14.5 Discussion 298

14.6 Conclusion 299

References 299

15 IoT for E-Mobility 301
Shanmugasundaram Logeshkumar, Krishnakumar Shanmugasundaram, Rahiman Zahira, Palanisamy Sivaraman, and Chenniappan Sharmeela

Introduction 301

15.1 What Is IoT for E-Mobility? 301

15.2 Benefits of IoT for E-Mobility 302

15.3 Challenges of IoT for E-Mobility 302

15.4 The Future of IoT for E-Mobility 303

15.5 Various Considerations and Possibilities of IoT for E-Mobility 304

15.6 Conclusion 331

References 332

16 Standards for Internet of Things (IoT) 335
Mohamed Mustafa Mohamed Iqbal, Balasubramanian Nandhan, Sakthivel Sruthi, Ravikumar Mithra, Rajagopal Logesh Krishna, Rahiman Zahira, Balan Gunapriya, and Veerasamy Balaji

16.1 Introduction 335

16.2 Smart Grid, Smart Transportation, and Smart Cities 336

16.3 Standardization of IoT Environment 337

16.4 IoT Standards in Healthcare 338

16.5 IoT Standards in Agriculture and Food Industry 341

16.6 IoT Standards in Smart Home and Industrial Automation 347

16.7 IoT Standards for Disaster Management 351

16.8 IoT Standards in Cybersecurity and Data Science Domain 353

16.9 Research Scope for Future Work 355

16.10 Conclusion 355

References 356

17 Challenges and Future Directions 363

Burhan Khan, Aabid A. Mir, Nur F.L.M. Rosely, and Khang W. Goh

17.1 Introduction 363

17.2 Security and Privacy Concerns in Transactive Systems 366

17.3 Scalability and Standardization Issues 370

17.4 Emerging Trends in Transactive IoT 373

17.5 Future Developments in Transactive IoT 376

17.6 Policy, Regulation, and Ethical Considerations 378

17.7 Conclusion 380

References 382

Index 387