Digital Convergence in Intelligent Mobility Systems

著者名：Gatti, Rathishchandra R. (EDT)/Singh, Chandra (EDT)

Wiley-Scrivener（2025/07/09発売）

• 言語：ENG
• ISBN：9781394275243
• eISBN：9781394275250

Description

Digital Convergence in Intelligent Mobility Systems gives a comprehensive understanding of how digital technologies are revolutionizing transportation, equipping you with the insights needed to navigate the future of intelligent mobility systems.

The rapid evolution of digital technologies has transformed the landscape of intelligent mobility systems, ushering in a new era of innovation and convergence. The integration of digital technologies into various aspects of mobility systems, such as autonomous vehicles, smart transportation networks, and advanced traffic management systems, has the potential to revolutionize how we move people and goods.

Digital Convergence in Intelligent Mobility Systems is a comprehensive guide that explores the intersection of digital convergence and intelligent mobility systems. This book aims to provide an in-depth understanding of the state-of-the-art technologies, methodologies, and applications that are reshaping the future of transportation. It will serve as a valuable resource for researchers, engineers, policymakers, and students interested in the field of intelligent mobility.

Table of Contents

Preface xv

1 Arduino-Based Battery-Operated Multi-Purpose Portable Seed-Sowing Machine 1
K. Raju, M. Ajay Kumar and Canute Sherwin

1.1 Introduction 2

1.2 Background 4

1.3 Design Details of Seed-Sowing Machine 8

1.3.1 Selection of DC Motor 8

1.3.1.1 Rolling Resistance 8

1.3.1.2 Grade Resistance 9

1.3.1.3 Acceleration Force 9

1.3.1.4 Total Tractive Effort 9

1.3.1.5 Torque 10

1.3.1.6 Output Speed 10

1.3.1.7 Power 10

1.3.1.8 Battery Capacity Calculation 10

1.3.1.9 Run Time of the Battery 11

1.3.1.10 Battery Stand-By Time 11

1.4 Details of Components of Seed-Sowing Machine 11

1.4.1 Mechanical Components 11

1.4.1.1 Hopper 11

1.4.1.2 Wheel 12

1.4.1.3 Shaft and Bearing 12

1.4.1.4 Chain Drive and Sprocket Assembly 12

1.4.1.5 Tilling Tool 13

1.4.1.6 Trenching Tool 13

1.4.1.7 Leveling Tool 13

1.4.2 Electrical and Electronic Components 14

1.4.2.1 Battery 14

1.4.2.2 dc Motor 15

1.4.2.3 Servo Motor 15

1.4.2.4 Relay 16

1.4.2.5 Arduino 16

1.5 Methodology 16

1.5.1 Block Diagram of the Proposed Seed-Sowing Machine 16

1.5.2 CAD Modeling of Seed-Sowing Machine 17

1.5.3 The Working Principle of the Seed-Sowing Machine 17

1.6 Results and Discussion 19

1.7 Scope for Future Work 20

1.8 Conclusions 20

References 21

2 An Overview of Intelligent Mobility of Agricultural Drones 25
Prasad G., Sukumar Dhanapalan, Brandon Bernard Chiripanyanga, Trycene Tadiwanashe Tsabora and Felix Mwiya

Introduction 26

Background of the Research 26

Technology in Agriculture 29

Using Unmanned Aerial Vehicles in Animal Farming 31

Design Flow Process 32

Management Team, GTM Strategy, and Competitive Landscape 33

Design Constraints 34

Conclusion 35

References 36

3 Simulation of Proportional-Integral and Derivative (PID) Based Traction and Speed Control System for a Four-Wheel Electric Vehicle Using MATLAB Simulink 39
Canute Sherwin, Christina Sundari, Aryan Bakle and Mahijit Dodiya

3.1 Introduction 40

3.2 Literature Review 41

3.3 Methodology 44

3.4 Results and Analysis 51

3.5 Conclusion 55

References 56

4 A Case Study on Electric Vehicles (EV) 59
Sumiksha Shetty, Smitha A. B., Manjunatha Badiger and Chandra Singh

4.1 Introduction 60

4.2 Literature Survey 61

4.3 Government Initiatives 63

4.3.1 Faster Adoption and Manufacturing of Hybrid and Electric Vehicles (FAME II) Scheme 63

4.3.2 National Electric Mobility Mission Plan (nemmp) 2020 63

4.3.3 Charging Infrastructure for Electric Vehicles— Guidelines and Standards of the Ministry of Power 64

4.3.4 State Government Initiatives 64

4.3.5 Public Sector Undertakings (PSUs) and Private Sector Collaboration 64

4.3.6 Smart Cities Mission 65

4.3.7 National Electric Mobility Infrastructure (NEMI) Guidelines 65

4.4 Challenges 66

4.4.1 Capital Intensive Investments 66

4.4.2 Power Supply and Grid Stability 66

4.4.3 The Issue of Uniformity in Charging Infrastructure 67

4.4.4 Space and Land Constraints 68

4.4.5 Legal and Bureaucratic Obstacles 68

4.4.6 Technology and Maintenance 69

4.4.7 Adoption Rate of EVs 70

4.4.8 Integration with Renewable Energy 70

4.5 Important Factors 71

4.6 Infrastructure 72

4.6.1 Charging Stations 72

4.6.2 Grid Upgrades 73

4.6.3 Battery Swapping Stations 74

4.6.4 Software Systems 74

4.7 Applications 75

4.8 Conclusion 76

References 76

5 Accelerating Connections with 5G and Evolution of Vehicle Communication Technology 79
Dankan Gowda V., Chippy T., V. Nuthan Prasad, Belsam Jeba Ananth M. and K.D.V. Prasad

5.1 Introduction 80

5.2 Historical Evolution of Vehicle Communication Technology 83

5.3 Foundations of 5G Technology 85

5.4 Integration of 5G in Vehicular Networks 87

5.5 Benefits of 5G in Automotive Communication 90

5.6 V2X Communication and 5G 92

5.7 Case Studies 93

5.8 Challenges and Future Directions 95

5.9 Conclusion 97

References 98

6 Predicting the Flow with Machine Learning Algorithms for Advanced Traffic Management 101
Dankan Gowda V., Rupali Suraskar, Ridhi Rani, K.D.V. Prasad and Ved Srinivas

6.1 Introduction 102

6.2 Fundamentals of Machine Learning in Traffic Management 105

6.3 Applications of ML in Traffic Prediction and Management 107

6.4 Case Studies 110

6.5 Challenges and Limitations 112

6.6 Future Trends and Innovations 115

6.7 Conclusion 118

References 120

7 Secure Routes and Cybersecurity Challenges in Autonomous Mobility Systems 125
Dankan Gowda V., Ribhu Abhusan P., V. Nuthan Prasad, K.D.V. Prasad and P. Vishnu Prasanth

7.1 Introduction 126

7.2 The Landscape of Autonomous Mobility 129

7.3 Cybersecurity Challenges 132

7.4 Secure Routes: Ensuring Safety in Navigation and Control 135

7.5 Defensive Technologies and Strategies 138

7.6 Regulatory and Standardization Efforts 141

7.7 Ethical and Privacy Considerations 144

7.8 Case Studies of Secure Autonomous Mobility Implementations 147

7.9 Future Directions and Research Opportunities 150

7.10 Conclusion 153

References 155

8 Green Routes Building the Backbone for Electric Vehicle Charging 159
Dankan Gowda V., Sadashiva V. Chakrasali, Ved Srinivas, K.D.V. Prasad and Saptarshi Mukherjee

8.1 Introduction 160

8.2 Current State of EV Charging Infrastructure 163

8.3 Technological Innovations in EV Charging 166

8.4 Designing Sustainable Charging Networks 169

8.5 Integration with Renewable Energy Sources 172

8.6 Economic and Business Models 176

8.7 Policy, Regulations, and Standards 178

8.8 Public Perception and Adoption 182

8.9 Future Directions and Innovations 185

8.10 Conclusion 187

References 189

9 Vehicular Power Line Communication 193
Smitha Gayathri D., K.R. Usha Rani and Yasha Jyothi Shirur

9.1 Introduction 194

9.2 Review and Categorization of Impedance Matching Techniques in Existing Literature 197

9.2.1 Impedance Matching: Concept and Classification 198

9.2.2 Related Works and Developments 199

9.3 Model of Vehicular Power Line Communication 200

9.3.1 The Resonance and Absorption Technique for Advanced Impedance Matching 201

9.3.1.1 Matching the Impedance to Access Inductive Impedance 201

9.3.1.2 System Structure 204

9.4 Simulation Results besides Analysis 208

9.5 Conclusion 213

References 213

10 Future Trends in V2X Communication and Interoperability 217
Dankan Gowda V., D. Palanikkumar, Satish Dekka, K.D.V. Prasad and Shivoham Singh

10.1 Introduction 218

10.2 Emerging Technologies in V2X Communication 221

10.3 Autonomous Vehicles and V2X Integration 223

10.4 Edge Intelligence and Decentralized Communication 226

10.5 Interoperability in a Multi-Vendor Ecosystem 229

10.6 Cybersecurity in Future V2X Systems 231

10.7 Environmental and Sustainability Considerations 232

10.8 User Experience and Human-Machine Interaction 234

10.9 Conclusion 236

References 237

11 Toward Smarter Streets: Leveraging Machine Learning, 5G, and V2X Communication for Traffic Insights 241
Smitha A. B., Manjunatha Badiger, Sumiksha Shetty, Chinmaya H., Sanketh C. Naik, Sujan R. Arasa, Ajay Deepak Lobo and Shreyas K.

11.1 Introduction 242

11.2 Literature Survey 242

11.3 5G Technology and Its Role in Transportation 249

11.4 Vehicular Communication and V2X Standards 250

11.4.1 Overview of Vehicular-to-Everything (V2X) Communication Technologies 250

11.4.2 V2X Communication Standards and Protocols 252

11.4.3 Importance of Interoperability for Seamless Communication between Vehicles and Infrastructure 254

11.5 Integration of Machine Learning with 5G and V2X Communication 255

11.5.1 Introduction to Machine Learning Algorithms Used in Traffic Prediction 255

11.5.2 Overview of Data Sources and Features Used for Training Traffic Prediction Models 256

11.5.3 Challenges and Opportunities in Integrating Machine Learning with 5G and V2X Communication 257

11.5.4 Potential Applications of Machine Learning in Optimizing Traffic Flow and Management 258

11.6 Dynamic Traffic Prediction and Management 259

11.6.1 Real-Time Data Utilization for Dynamic Traffic Prediction 259

11.6.2 Techniques for Route Optimization and Vehicle Rerouting 260

11.6.3 Machine Learning and V2X in Dynamic Traffic Signal Optimization 260

11.6.4 Benefits of Adaptive Traffic Signal Control in Improving Traffic Flow and Reducing Congestion 261

11.6.5 Safety Applications and Collision Avoidance Systems 261

11.7 Future Directions and Challenges 262

11.7.1 Emerging Trends and Future Directions in the Integration of Machine Learning, 5G, and V2X Communication 262

11.7.2 Addressing Challenges 263

11.7.3 Opportunities for Further Research and Development in the Field of Intelligent Transportation Systems 264

11.8 Conclusion 264

References 265

12 Empowering Healthcare through Mobility as a Service: A Comprehensive Review 271
Manjunatha Badiger, Thrisha B., Kshithij H. S., Sathwik M. S. and Rakshitha N.

12.1 Introduction 272

12.2 Mobility as a Service (MaaS) in Healthcare 274

12.2.1 Overview of Healthcare Access Challenges 274

12.2.2 Enhancing Medical Access with Mobility as a Service 275

12.3 Low-Cost Generic Medicine Dispensers 277

12.4 Regulatory and Infrastructure Considerations 279

12.4.1 Challenges and Solutions 279

12.4.2 Strategic Partnerships and Stakeholder Engagement 280

12.4.3 Funding and Sustainability Models 280

12.4.4 Technology Integration and Digital Connectivity 281

12.4.5 User Education, Community Engagement, and Security Measures 281

12.5 Assessing Impact: Benefits to Healthcare, Economy, and Society 282

12.5.1 Environmental Considerations 282

12.5.2 Improved Public Health Outcomes 283

12.5.3 Enhanced Data Analytics and Health Insights 283

12.6 Future Perspective Empowering Healthcare MAAS to Support Healthcare 284

12.6.1 Environmental Considerations 285

12.7 Cost Reduction and Efficiency in Healthcare Delivery 287

References 288

13 An Enhanced Sustainable Mobility as a Service Based on 5G Network for Human-Centric Mobile Network in Smart City 293
Senthil G. A., R. Prabha, D. Roopa and S. Sridevi

13.1 Introduction 294

13.1.1 Objective and Benefits 295

13.2 Proposed Enhanced MaaS Framework 297

13.2.1 System Architecture 297

13.2.2 Service Components 298

13.2.3 Human-Centric Design 300

13.2.4 Mobility Analysis 300

13.3 Sustainability Analysis 301

13.3.1 Environmental Impact 301

13.3.2 Social Impact 302

13.3.3 Economic Impact 303

13.4 Challenges and Solutions 304

13.4.1 Technological Challenges 304

13.4.2 Communication Network and Bandwidth 305

13.4.3 Enabling Critical Infrastructures 306

13.4.4 Social and Regulatory Challenges 307

13.4.5 Quality of Service 308

13.5 Conclusion 309

13.6 Future Work 310

References 311

14 Design and Development of Foldable Electric Vehicle 315
Akshay S. Bhat, Puneeth H. S., P. Aniketh Solanki, Karthik P., Prajwal K. Kalal and Manoj S.

14.1 Introduction 315

14.2 Problem Formulation 317

14.3 Methodology and Material 318

14.3.1 Material Selection Process 319

14.3.2 Working 320

14.3.3 Electrical Components 320

14.4 Static Analysis 327

14.5 Results 328

14.6 Conclusion 329

References 330

15 Design and Development of Ultrasonic Assisted Collision Detection and Blind-Spot Reduction 331
Puneeth H. S., Akshay S. Bhat, Bhavani A., Lalit V., Sathyarjun A. B. and Vishnu K. J.

15.1 Introduction 332

15.1.1 Head-Up Display 333

15.1.2 Elements That Control IC Engine Vehicles’ Speed 333

15.1.2.1 Electronic Control Unit 333

15.1.2.2 Sensors Operated by ECU 334

15.1.2.3 Air–Fuel Ratio 334

15.1.2.4 Air–Fuel Ratio and Engine Performance 335

15.1.2.5 Throttle Body 335

15.1.3 Components Associated with the Vehicle Speed in EVs 335

15.1.3.1 Throttle 336

15.1.3.2 Motor 336

15.1.3.3 Controller 336

15.2 Problem Formulation 337

15.2.1 Integration of Head-Up Display 337

15.2.2 Vehicle Speed Controller 337

15.3 Methodology 338

15.3.1 Components Used 338

15.3.2 Construction and Working 338

15.4 Scope of the Project 341

15.4.1 Implementation in IC Engines 341

15.4.2 Implementation in Electric Vehicle 342

15.4.3 Head-Up Display 343

15.5 Results and Discussions 343

15.5.1 Results 343

15.5.2 Discussions 343

15.6 Conclusion 344

References 345

16 Voting Classifier-Based Machine Learning Technique for the Prediction of the Traffic Flow for the Intelligent Transportation System 347
Sandeep Kumar Hegde, Rajalaxmi Hegde and Thangavel Murugan

16.1 Introduction 348

16.2 Literature Review 350

16.3 Methodology 353

16.4 Experimental Results 355

16.5 Conclusion 360

References 360

17 Influence of Feature Selection Techniques for Social Media Data Analysis (Text and Image) 363
Aruna Bajpai and Yogesh Kumar Gupta

17.1 Introduction 364

17.2 Literature Review 364

17.3 Proposed Work 369

17.3.1 Text Feature Analysis 369

17.3.2 Image Feature Analysis 370

17.4 Results Analysis 373

17.5 Conclusions 375

Bibliography 376

About the Editors 379

Index 381