Optimizing AI Applications for Sustainable Agriculture

Roheet Bhatnagar, PhD is a Professor in the Department of Computer Science and Engineering at Manipal University, Jaipur, Rajasthan, India with over 22 years of experience. He has published more than 100 research papers in reputed conferences and journals and edited five books. His research focuses on soft computing, data structure, and software engineering. Chandan Kumar Panda, PhD is an Assistant Professor at Bihar Agricultural University, Sabour, Bihar, India with over eight years of research and teaching experience. He has published three books, 16 book chapters, and more than 50 research papers in international journals and conferences. He is an acclaimed researcher in ICT in the agriculture sector. His research interests include agricultural extension, rural development, and information and communication technology in agriculture. Mahmoud Yasin Shams, PhD is an Associate Professor of Machine Learning and Information Retrieval in the School of Artificial Intelligence, Kafrelsheikh University, Kafr el-Sheikh, Egypt. With over 70 papers and conference presentations published in top-tier journals he has made significant contributions to the field. He specializes in artificial intelligence, machine learning, pattern recognition, and classification.

Preface xxi

Part I: Artificial Intelligence-Assisted Sustainable Agriculture 1

1 AI and Emerging Technologies for Precision Agriculture: A Survey 3
Brajesh Kumar Khare

1.1 Introduction 4

1.2 Precision Agriculture 5

1.3 Artificial Intelligence 9

1.3.1 Role of AI in Agriculture 11

1.4 Internet of Things (IoT) 11

1.4.1 Basics of IoT in Agriculture 13

1.4.2 Role of IoT 15

1.5 Blockchain Technology 15

1.6 Technologies Used in Smart Farming 17

1.6.1 Global Positioning System (GPS) 17

1.6.2 Sensor Technologies 17

1.6.3 Variable Rate Technology and Grid Soil Sampling 18

1.6.4 Geographic Information System (GIS) 19

1.6.5 Crop Management 19

1.6.6 Soil and Plant Sensors 20

1.6.7 Yield Monitor 20

1.7 Challenges 24

1.8 Future Research 26

1.9 Conclusion 29

References 29

2 AI-Enabled Framework for Sustainable Agriculture Practices 33
Yukti Batra, Suman Bhatia and Ankit Verma

2.1 Introduction 34

2.2 Sustainable Agriculture Imperatives 35

2.2.1 Environmental Degradation 36

2.2.2 Biodiversity Loss 36

2.2.3 Climate Change Impacts 36

2.2.4 Resource Scarcity 37

2.2.5 Food Security and Economic Stability 37

2.2.6 Public Health Concerns 37

2.2.7 Social Equity and Rural Livelihoods 37

2.2.8 Global Food Shortage Concerns 38

2.2.9 Empowerment and Awareness 38

2.3 Social Relevance of Sustainable Practices in Agriculture 38

2.3.1 Livelihood Security 39

2.3.2 Community Health and Well-Being 39

2.3.3 Social Equity and Inclusion 39

2.3.4 Rural Empowerment and Resilience 40

2.4 Sustainable Agriculture Indicators 40

2.4.1 Food Grain Productivity 40

2.4.2 Population Density 41

2.4.3 Cropping Intensity 42

2.5 Sustainable Agriculture Practices Followed Till Date 42

2.5.1 Agroforestry 42

2.5.2 Integrated Pest Management (IPM) 44

2.5.3 Crop Rotation 44

2.5.4 Cover Cropping 44

2.5.5 Organic Farming 44

2.5.6 No-Till Farming 44

2.6 AI-Enabled Conceptual Framework 44

2.6.1 Perception from Environment Using IoT Sensors 45

2.6.1.1 Remote Sensing 45

2.6.1.2 IoT Sensors 46

2.6.2 Data Storage 46

2.6.3 Data Processing 47

2.6.4 Training and Testing by ML Models 47

2.7 Applications of Artificial Intelligence in Agriculture 48

2.8 Challenges and Barriers to Sustainable Agriculture 51

2.8.1 Theoretical Obstacles 51

2.8.2 Methodological Obstacles 52

2.8.3 Personal Obstacles 53

2.8.4 Practical Obstacles 54

2.9 Future Directions 55

2.10 Conclusion 57

References 58

3 The Impact of Artificial Intelligence on Agriculture: Revolutionizing Efficiency and Sustainability 61
Santhiya S., P. Jayadharshini, N. Abinaya, Sharmila C., Srigha S. and Sruthi K.

Applications 62

3.1 Introduction 62

3.2 Precision Farming 64

3.2.1 Data Collection and Analytics 64

3.2.2 Disease Detection 65

3.2.3 Yield Production and Optimization 65

3.2.4 Precision Irrigation 66

3.3 Crop Monitoring 67

3.3.1 Remote Sensing and Satellite Imagery 67

3.3.2 Drones 67

3.3.3 Computer Vision and Image Analysis 68

3.3.4 Sensor Network and IoT 68

3.3.5 Weed Detection Management 68

3.4 AI in Aquaculture 69

3.4.1 Monitoring Water Quality 69

3.4.2 Feed Management 70

3.4.3 Breeding Technique 70

3.4.4 Autonomous Systems and Market Optimization 70

3.5 Predictive Analysis 71

3.5.1 Irrigation Optimization 71

3.5.2 Supply Chain Management 72

3.5.3 Weather and Climate Modeling 72

3.5.4 Equipment Maintenance 73

3.6 Robotics and Automation in AI Agriculture 73

3.6.1 Robotic Planting System 73

3.6.2 Automated Irrigation Systems 74

3.6.3 AI-Driven Crop Monitoring 75

3.6.4 Harvesting Robots 75

3.7 Livestock Monitoring 75

3.7.1 Video and Image Analysis 76

3.7.2 Health Monitoring 76

3.7.3 Behavior Analysis 77

3.7.4 Predictive Analysis 77

3.7.5 Environment Analysis 77

3.7.6 Disease Analysis and Prediction 78

3.8 AI for Climate Smart Agriculture 78

3.8.1 Climate Prediction and Weather Forecasting 79

3.8.2 Enhancing Resilience to Climate Variability 79

3.8.3 Water Management 80

3.8.4 Reducing Greenhouse Gas Emissions 80

3.8.5 Increasing Productivity and Sustainability 80

3.9 AI in Agroecology 81

3.9.1 Decision Support Systems 81

3.9.2 Biodiversity Conservation 82

3.9.3 Soil Health Management 82

3.10 Soil Analysis 83

3.10.1 Soil Classification 83

3.10.2 Soil Nutrient Management 83

3.10.3 Disease and Pest Detection 84

3.10.4 Soil Moisture Monitoring 84

3.10.5 Precision Agriculture 84

3.10.6 Soil Erosion Prediction 85

3.10.7 Soil Remediation 85

3.11 Conclusion 86

Bibliography 87

4 Integrating Artificial Intelligence into Sustainable Agriculture: Advancements, Challenges, and Applications 89
Djamel Saba and Abdelkader Hadidi

4.1 Introduction 90

4.2 Literature Review 92

4.3 Key Critical Challenges of Conventional Agriculture 97

4.3.1 Overview of Conventional Agriculture 97

4.3.2 The Distinction Between Agriculture in the Past and Now 99

4.4 AI Technologies and Sustainable Agriculture 103

4.5 Artificial Intelligence’s Practical Use in Farming 104

4.6 Challenges and Ethical Considerations 107

4.6.1 Challenges 107

4.6.1.1 Data Privacy and Security 107

4.6.1.2 Accessibility and Inclusivity 107

4.6.1.3 Algorithm Bias 107

4.6.1.4 Interoperability and Standardization 107

4.6.1.5 Job Displacement 108

4.6.2 Ethical Considerations 108

4.6.2.1 Transparency and Accountability 108

4.6.2.2 Environmental Impact 108

4.6.2.3 Informed Consent 108

4.6.2.4 Fair Distribution of Benefits 109

4.6.2.5 Long-Term Sustainability 109

4.7 Conclusions and Further Work 109

References 110

5 Artificial Intelligence for Sustainable and Smart Agriculture 117
Djamel Saba and Abdelkader Hadidi

5.1 Introduction 118

5.2 Literature Review 120

5.3 AI Techniques for Revolutionizing Traditional Farming 125

5.4 Role of the IoT in Smart Farms 128

5.4.1 Smart Farming Technologies 130

5.4.1.1 Precision Agriculture 130

5.4.1.2 Livestock Monitoring 130

5.4.1.3 Crop Monitoring 130

5.4.2 Climate Management and Weather Forecasting 130

5.4.3 Supply Chain Optimization 131

5.4.4 Analytics and Assistance for Decision-Making 131

5.4.5 The Advantages and Difficulties of IoT in Agriculture 131

5.4.5.1 Advantages 131

5.4.5.2 Difficulties 131

5.5 Environmental Concerns Related to Agriculture 132

5.5.1 Environmental Concerns Related to Sustainable Agriculture 132

5.5.2 Environmental Concerns Related to Smart Agriculture 132

5.6 Challenges and Considerations 135

5.7 Conclusions and Further Work 137

References 142

6 Data-Driven Approaches for Sustainable Agriculture and Food Security 145
S.C. Vetrivel, V. Sabareeshwari, K.C. Sowmiya and V.P. Arun

6.1 Introduction 146

6.1.1 The Role of Data in Agriculture 146

6.1.2 Importance of Sustainability and Food Security 147

6.1.3 Overview of Data-Driven Technologies 148

6.2 Big Data in Agriculture 150

6.2.1 Definition and Characteristics of Big Data 150

6.2.2 Applications of Big Data in Agriculture 151

6.2.3 Challenges and Opportunities 152

6.2.3.1 Challenges 152

6.2.3.2 Opportunities 153

6.3 Internet of Things (IoT) in Agriculture 154

6.3.1 Understanding IoT and Its Components 154

6.3.2 IoT Applications in Farming 155

6.3.3 Benefits and Challenges of IoT Implementation 156

6.4 Artificial Intelligence and Machine Learning in Agriculture 157

6.4.1 Fundamentals of AI and Machine Learning 157

6.4.2 AI and ML Applications in Crop Monitoring and Management 158

6.4.3 Predictive Analytics for Yield Optimization 159

6.5 Remote Sensing and GIS in Agriculture 159

6.5.1 Remote Sensing Technologies Overview 159

6.5.2 GIS Mapping for Precision Agriculture 160

6.5.3 Monitoring Environmental Impact and Land Use 161

6.6 Data-Driven Approaches for Sustainable Crop Management 162

6.6.1 Precision Agriculture Techniques 162

6.6.2 Crop Disease Detection and Management 162

6.6.3 Water Management and Irrigation Systems 163

6.7 Data-Driven Livestock Management 163

6.7.1 Monitoring Animal Health and Welfare 163

6.7.2 Precision Livestock Farming 164

6.7.3 Sustainable Feed Management 164

6.8 Supply Chain Management and Food Security 165

6.8.1 Traceability and Transparency in the Food Supply Chain 165

6.8.2 Data-Driven Approaches for Food Distribution 165

6.8.3 Enhancing Food Security through Data Analytics 166

6.9 Policy Implications and Ethical Considerations 167

6.9.1 Regulatory Frameworks for Data-Driven Agriculture 167

6.9.2 Ethical Issues Surrounding Data Collection and Privacy 167

6.9.3 Balancing Innovation with Social Responsibility 168

6.10 Future Trends and Conclusion 168

6.10.1 Emerging Technologies and Trends 168

6.10.2 Potential Impact on Sustainable Agriculture and Food Security 169

6.11 Conclusion 170

References 170

Part II: Recent Developments in Crop Disease Detection and Prevention 175

7 Advances in Plant Disease Detection and Classification Systems 177
Bhakti Sanket Puranik, Karanbir Singh Pelia, Shrivatsasingh Khushal Rathore and Vaibhav Vikas Dighe

7.1 Introduction 178

7.2 Literature Review 179

7.3 Methodologies and Techniques 185

7.3.1 CNN Architectures 185

7.3.2 Activation Functions 186

7.3.3 Loss Functions 187

7.3.4 Learning Rate Schedulers 187

7.3.5 Early Stopping 188

7.3.6 Checkpoints and Callbacks 188

7.3.7 Data Preprocessing 189

7.3.8 Data Augmentation 189

7.3.9 Transfer Learning 190

7.3.10 Ensemble Learning 191

7.4 Challenges and Limitations 191

7.4.1 Dataset Scarcity 192

7.4.2 Image Variability 192

7.4.3 Label Inconsistency 193

7.4.4 Model Interpretability 193

7.5 Proposed Model 194

7.5.1 Model Architecture 195

7.5.2 Training Mechanism 196

7.6 Future Scope 198

7.6.1 Development of Comprehensive Datasets 199

7.6.2 Exploration of Novel Architectures 199

7.6.3 Integration of Advanced Technologies 200

7.6.4 Crowdsourcing New Data 201

7.6.5 Adaptation and Interaction 201

7.6.6 Integrated Remediation Strategies 202

7.7 Conclusion 203

References 204

8 Ensemble-Based Crop Disease Biomarker Multi-Domain Feature Analysis (ECDBMFA) 207
Chilakalapudi Malathi and Sheela J.

8.1 Introduction 208

8.2 Literature Survey 208

8.3 Design of ECDBMFA 210

8.4 Result Evaluation and Comparative Analysis with Existing Techniques 217

8.5 Conclusion 226

References 226

9 Artificial Intelligence and Machine Learning in Crop Yield Prediction and Pest Control 231
Archana Negi, Jitendra Singh, Robin Kumar, Atin Kumar, Nisha and Sharad Sachan

Introduction 232

Artificial Intelligence 234

Machine Learning 235

AI-Based ML Algorithm Models 237

Some Important Evaluation Metrics Used in AI-Based Predictive Models 239

Applications of Artificial Intelligence and Machine Learning in Crop Yield Prediction Models 241

AI-Based Crop Yield Prediction Method—Case Study 242

Steps for Crop Yield Prediction 243

Applications of Artificial Intelligence and Machine Learning in Pest and Disease Management 244

Advantages of Using Artificial Intelligence/Machine Learning in Agriculture 248

Challenges of Artificial Intelligence and Machine Learning Application in Agriculture 249

Conclusion and Future Prospects 250

References 250

10 Farming in the Digital Age: A Machine Learning Enhanced Crop Yield Prediction and Recommendation System 257
Arti Sonawane, Akanksha Ranade, Apurva Kolte, Siddharth Daundkar and Shreyas Rajage

10.1 Background 258

10.2 Introduction 260

10.3 Importance 261

10.4 Machine Learning in Agriculture 262

10.5 Objectives 267

10.6 Related Work 267

10.6.1 Research Gaps 276

10.7 Proposed Methodology 277

10.7.1 Data Collection 277

10.7.2 Data Preprocessing 277

10.7.3 Training and Testing Model 278

10.7.4 Decision Tree Repressor 278

10.7.5 Random Forest Regressor 279

10.8 Implications for Farmers 282

10.9 Future Directions 284

10.10 Conclusion 285

References 285

Part III: IoT and Modern Agriculture 289

11 Digital Agriculture: IoT Applications and Technological Advancement 291
K. Aditya Shastry

11.1 Introduction 292

11.2 Related Work 296

11.3 Emerging Technologies and Related Applications in Smart Agriculture 299

11.3.1 Internet of Things (IoT) in Agriculture 300

11.3.2 Artificial Intelligence (AI) and Machine Learning (ml) 300

11.3.3 Remote Sensing (RS) and Satellite Technology 302

11.3.4 Blockchain Technology 305

11.3.5 Robotics and Automation 309

11.3.6 Sustainable Agriculture Practices 310

11.4 Challenges in Smart Farming 315

11.5 Future Trends in Smart Farming 317

11.6 Conclusion 320

References 320

12 IoT in Climate-Smart Farming 323
Maitreyi Darbha, S. V. Sanjay Kumar, S. R. Mani Sekhar and Sanjay H. A.

12.1 Introduction 323

12.2 IoT in Agriculture 325

12.2.1 What is IoT? 325

12.2.2 Methods Involved in the Incorporation of IoT in Agriculture 325

12.2.2.1 Greenhouse Farming 325

12.2.2.2 Vertical Farming 326

12.2.2.3 Hydroponics 326

12.2.2.4 Phenotyping 327

12.2.3 Resources Required for the Incorporation 328

12.3 Climate-Smart Farming Practices 329

12.3.1 What is Climate-Smart Farming? 329

12.3.2 Integration of IoT 330

12.3.2.1 Precision Farming 330

12.3.2.2 Smart Irrigation 331

12.3.2.3 Crop Monitoring 331

12.3.2.4 Livestock Management 331

12.3.3 Environmental Impact and Resilience to Climate Change 332

12.4 Case Studies 333

12.4.1 IoT Applications in Precision Agriculture 333

12.4.1.1 Weather Monitoring 333

12.4.1.2 Soil Content Monitoring 333

12.4.1.3 Diseases Monitoring 334

12.4.2 IoT Applications in Greenhouse 334

12.5 Evaluation of IoT Technologies 336

12.5.1 Effectiveness of IoT Technologies 336

12.5.2 Comparison with Traditional Methods 336

12.5.3 Advantages and Disadvantages 337

12.6 Relevance to Current-Day Global Issues 338

12.6.1 Future Scope 338

12.7 Conclusion 339

References 340

Part IV: Technological Trends and Advancements in the Agricultural Sector 345

13 Sustainable Agriculture Practices with ICT for Soil Health Management 347
Bhabani Prasad Mondal, Anshuman Kohli, Ingle Sagar Nandulal, Roheet Bhatnagar, Chandan Kumar Panda, Sonal Kumari, Bharat Lal, Sai Parasar Das, Chandrabhan Patel, Vimal Kumar, Achin Kumar, Karad Gaurav Uttamrao, Suman Dutta and Ali R.A. Moursy

13.1 Introduction 348

13.2 Advanced ICT Technologies 350

13.2.1 Gps 350

13.2.2 Gis 351

13.2.3 Dss 352

13.2.4 Remote Sensing 352

13.2.5 IoT 353

13.2.6 Sensor Technology 354

13.2.7 Grid Soil Sampling and Variable Rate Technology (vrt) 356

13.2.8 Agricultural Robotics 357

13.3 Application of ICT in Soil Health Management 358

13.3.1 Artificial Intelligence in Analyzing Soil Health Parameters 358

13.3.1.1 Data Collection 358

13.3.1.2 Data Preprocessing 358

13.3.1.3 Feature Selection 358

13.3.1.4 Model Training 359

13.3.1.5 Model Validation 359

13.3.1.6 Soil Health Parameter Prediction 359

13.3.2 Fertilizer Recommendation Using ICT 359

13.3.2.1 Soil App 360

13.3.2.2 Multimodal DSS in Soil Fertility Management 360

13.3.3 Smart Soil Health Management Using Sensor-Based Technology 362

13.3.3.1 Sensor Selection 362

13.3.3.2 Sensor Placement 362

13.3.3.3 Data Collection 362

13.3.3.4 Data Processing 362

13.3.4 Real-Time Monitoring 363

13.3.4.1 Sensors’ Efficiency Evaluation 363

13.3.5 Satellite and Drone-Based Remote Sensing Technology in Soil Health Management 363

13.3.6 ICT-Based Soil Conservation for Soil Health Management 364

13.3.7 Autonomous Robots in Efficient Soil Health Management 365

13.4 Challenges in Implementing ICT-Based Technologies 365

13.4.1 Lack of Availability of Accurate Data 365

13.4.2 High Cost of Technology and Higher Investment 366

13.4.3 Lack of Sound Skill and Knowledge of Farmers 366

13.4.4 Lack of Communication Structure and Support 367

13.4.5 Low-Risk–Bearing Capacity of Farmers 367

13.5 Opportunities or Pathways to Tackle the Issues in ICT-Based Soil Management 367

13.6 Conclusion 369

Acknowledgment 370

References 370

14 Water Resource Management Model for Smart Agriculture 375
Aysulu Aydarova

Introduction 375

Main Part 376

Conclusion 397

References 398

15 A Big Data Analytics–Based Architecture for Smart Farming 399
Tanvi Chawla, Tamanna Gahlawat and TanyaShree Thakur

15.1 Introduction 400

15.2 Related Work 402

15.3 Research Issues in Big Data for Smart Agriculture 404

15.4 Applications of Big Data Analytics in Smart Agriculture 405

15.5 Types of Big Data in Agriculture 407

15.6 Proposed Work 408

15.7 Conclusion and Future Work 414

References 414

16 Adoption of Blockchain Technology for Transparent and Secure Agricultural Transactions 417
S.C. Vetrivel, V. Sabareeshwari, K.C. Sowmiya and V.P. Arun

16.1 Introduction to Blockchain Technology 418

16.1.1 Definition and Overview 418

16.1.2 Evolution of Blockchain 418

16.1.3 Basic Components and Principles 419

16.1.4 Blockchain’s Significance in Agriculture 419

16.2 Challenges in Traditional Agricultural Transactions 420

16.2.1 Lack of Transparency 420

16.2.2 Security Issues 420

16.2.3 Trust Deficit 421

16.2.4 Inefficiencies in Supply Chain 421

16.3 Understanding Blockchain Solutions 422

16.3.1 How Blockchain Operates 422

16.3.2 Types of Blockchain 423

16.3.3 Smart Contracts and Their Role 424

16.3.4 Benefits of Blockchain in Agriculture 425

16.4 Use Cases of Blockchain in Agriculture 427

16.4.1 Produce Traceability 427

16.4.1.1 Tracking Farm to Fork 427

16.4.1.2 Quality Assurance 427

16.4.2 Supply Chain Management 428

16.4.2.1 Inventory Tracking 428

16.4.2.2 Real-Time Monitoring 428

16.4.3 Payment and Financing Solutions 428

16.4.3.1 Microfinancing for Farmers 428

16.4.3.2 Instant and Secure Payments 430

16.5 Implementing Blockchain in Agriculture 430

16.5.1 Infrastructure Requirements 430

16.5.2 Data Management and Integration 432

16.5.3 Regulatory Considerations 432

16.5.4 Challenges in Adoption 432

16.6 Case Studies and Success Stories 434

16.6.1 IBM Food Trust 434

16.6.2 Provenance 434

16.6.3 AgriDigital 434

16.7 Future Trends and Opportunities 435

16.7.1 Integration with IoT and AI 435

16.7.2 Expansion of Blockchain Applications 435

16.7.3 Potential Impact on Global Food Security 437

16.8 Conclusion 439

References 439

17 AI-Assisted Environmental Parameter Monitoring of Plants in Greenhouse Farming 445
K. Sujatha, N.P.G. Bhavani, R. S. Ponmagal, N. Shanmugasundaram, C. Tamilselvi, A. Ganesan and Suqun Cao

17.1 Introduction 446

17.2 Background 447

17.3 Importance of Smart Agriculture 448

17.4 Artificial Neural Network (ANN) 449

17.4.1 Mayfly Optimization 451

17.5 Problem Statement 453

17.6 Objectives 454

17.7 Strategy for Polyhouse Monitoring 454

17.8 Results and Discussion 460

17.9 Conclusion 467

References 469

18 Metaverse in Agricultural Training and Simulation 471
Syed Quadir Moinuddin, Himam Saheb Shaik, md Atiqur Rahman and Borigorla Venu

18.1 Introduction 471

18.2 AI in Agriculture 473

18.3 Metaverse 475

18.3.1 Agriculture with AI-Based Metaverse 476

18.4 Augmented Reality (AR) 478

18.5 Virtual Reality (VR) 480

18.6 Mixed Reality (MR) 482

18.7 Agriculture Training Simulations 485

18.8 Metaverse in Agriculture Trainings 487

18.9 Conclusions 488

Acknowledgment 489

References 489

19 Sustainable Farming in the Digital Era: AI and IoT Technologies Transforming Agriculture 493
Arti Sonawane, Suvarna Patil and Atul Kathole

19.1 Introduction 494

19.1.1 The Role of Artificial Intelligence in Agriculture 495

19.1.2 The Role of the Internet of Things in Agriculture 495

19.1.3 The Intersection of AI and IoT in Agriculture 496

19.1.4 The Importance of Sustainability in Agriculture 496

19.1.5 Problem Statement 497

19.1.6 Motivation 497

19.1.7 Objective 497

19.2 Related Work 498

19.2.1 Comparative Analysis of Existing Challenges 499

19.2.1.1 Precision Agriculture: Challenges in Future IoT (2023) 501

19.2.1.2 AI-Driven Precision Agriculture: Challenges and Perspectives (2023) 502

19.2.1.3 IoT and AI in Agriculture: An Overview (2022) 502

19.2.1.4 Smart Farming with IoT and AI: Benefits and Challenges (2022) 502

19.2.1.5 AI and IoT-Based Crop Monitoring: A Review (2023) 502

19.2.1.6 Integration of AI and IoT in Agriculture: State-of-the-Art and Future Trends (2023) 502

19.2.1.7 Sustainable Agriculture: The Role of IoT and AI (2022) 503

19.2.1.8 Advances in IoT and AI for Precision Agriculture (2022) 503

19.3 Discussion of Proposed Approach 503

19.3.1 System Architecture 504

19.3.2 Components and Tools 505

19.3.3 Result and Discussion 506

19.4 Application 508

19.5 Advantages and Disadvantages of System 509

19.6 Conclusion 510

Future Scope 510

References 511

20 Precision Agriculture with Unmanned Aerial Vehicles 513
Suresh S., Sampath Boopathi, Elayaraja R., Velmurugan D. and Selvapriya R.

20.1 Introduction 514

20.2 Agri-UAV Construction and Controls 516

20.3 Applications of UAVs in Agriculture 519

20.3.1 Crop Spraying 520

20.3.2 Crop Health Monitoring 524

20.3.3 Drone Seeding 527

20.4 Conclusion 529

References 530

Index 535