A comprehensive guide to Fog and Edge applications, architectures, and technologies
Recent years have seen the explosive growth of the Internet of Things (Io T): the internet-connected network of devices that includes everything from personal electronics and home appliances to automobiles and industrial machinery. Responding to the ever-increasing bandwidth demands of the Io T, Fog and Edge computing concepts have developed to collect, analyze, and process data more efficiently than traditional cloud architecture.
Fog and Edge Computing: Principles and Paradigms provides a comprehensive overview of the state-of-the-art applications and architectures driving this dynamic field of computing while highlighting potential research directions and emerging technologies.
Exploring topics such as developing scalable architectures, moving from closed systems to open systems, and ethical issues rising from data sensing, this timely book addresses both the challenges and opportunities that Fog and Edge computing presents. Contributions from leading Io T experts discuss federating Edge resources, middleware design issues, data management and predictive analysis, smart transportation and surveillance applications, and more. A coordinated and integrated presentation of topics helps readers gain thorough knowledge of the foundations, applications, and issues that are central to Fog and Edge computing. This valuable resource:
- Provides insights on transitioning from current Cloud-centric and 4G/5G wireless environments to Fog Computing
- Examines methods to optimize virtualized, pooled, and shared resources
- Identifies potential technical challenges and offers suggestions for possible solutions
- Discusses major components of Fog and Edge computing architectures such as middleware, interaction protocols, and autonomic management
- Includes access to a website portal for advanced online resources
Fog and Edge Computing: Principles and Paradigms is an essential source of up-to-date information for systems architects, developers, researchers, and advanced undergraduate and graduate students in fields of computer science and engineering.
Tabella dei contenuti
List of Contributors xix
Preface xxiii
Acknowledgments xxvii
Part I Foundations 1
1 Internet of Things (Io T) and New Computing Paradigms 3
Chii Chang, Satish Narayana Srirama, and Rajkumar Buyya
1.1 Introduction 3
1.2 Relevant Technologies 6
1.3 Fog and Edge Computing Completing the Cloud 8
1.3.1 Advantages of FEC: SCALE 8
1.3.2 How FEC Achieves These Advantages: SCANC 9
1.4 Hierarchy of Fog and Edge Computing 13
1.5 Business Models 16
1.6 Opportunities and Challenges 17
1.7 Conclusions 20
References 21
2 Addressing the Challenges in Federating Edge Resources 25
Ahmet Cihat Baktir, Cagatay Sonmez, Cem Ersoy, Atay Ozgovde, and Blesson Varghese
2.1 Introduction 25
2.2 The Networking Challenge 27
2.3 The Management Challenge 34
2.4 Miscellaneous Challenges 40
2.5 Conclusions 45
References 45
3 Integrating Io T + Fog + Cloud Infrastructures: System Modeling and Research Challenges 51
Guto Leoni Santos, Matheus Ferreira, Leylane Ferreira, Judith Kelner, Djamel Sadok, Edison Albuquerque, Theo Lynn, and Patricia Takako Endo
3.1 Introduction 51
3.2 Methodology 52
3.3 Integrated C2F2T Literature by Modeling Technique 55
3.4 Integrated C2F2T Literature by Use-Case Scenarios 65
3.5 Integrated C2F2T Literature by Metrics 68
3.6 Future Research Directions 72
3.7 Conclusions 73
Acknowledgments 74
References 75
4 Management and Orchestration of Network Slices in 5G, Fog, Edge, and Clouds 79
Adel Nadjaran Toosi, Redowan Mahmud, Qinghua Chi, and Rajkumar Buyya
4.1 Introduction 79
4.2 Background 80
4.3 Network Slicing in 5G 83
4.4 Network Slicing in Software-Defined Clouds 87
4.5 Network Slicing Management in Edge and Fog 91
4.6 Future Research Directions 93
4.7 Conclusions 96
Acknowledgments 96
References 96
5 Optimization Problems in Fog and Edge Computing 103
Zoltán Ádám Mann
5.1 Introduction 103
5.2 Background / Related Work 104
5.3 Preliminaries 105
5.4 The Case for Optimization in Fog Computing 107
5.5 Formal Modeling Framework for Fog Computing 108
5.6 Metrics 109
5.6.5 Further Quality Attributes 112
5.7 Optimization Opportunities along the Fog Architecture 113
5.8 Optimization Opportunities along the Service Life Cycle 114
5.9 Toward a Taxonomy of Optimization Problems in Fog Computing 115
5.10 Optimization Techniques 117
5.11 Future Research Directions 118
5.12 Conclusions 119
Acknowledgments 119
References 119
Part II Middlewares 123
6 Middleware for Fog and Edge Computing: Design Issues 125
Madhurima Pore, Vinaya Chakati, Ayan Banerjee, and Sandeep K. S. Gupta
6.1 Introduction 125
6.2 Need for Fog and Edge Computing Middleware 126
6.3 Design Goals 126
6.4 State-of-the-Art Middleware Infrastructures 128
6.5 System Model 129
6.6 Proposed Architecture 131
6.7 Case Study Example 136
6.8 Future Research Directions 137
6.9 Conclusions 139
References 139
7 A Lightweight Container Middleware for Edge Cloud Architectures 145
David von Leon, Lorenzo Miori, Julian Sanin, Nabil El Ioini, Sven Helmer, and Claus Pahl
7.1 Introduction 145
7.2 Background/Related Work 146
7.3 Clusters for Lightweight Edge Clouds 149
7.4 Architecture Management – Storage and Orchestration 152
7.5 Io T Integration 159
7.6 Security Management for Edge Cloud Architectures 159
7.7 Future Research Directions 165
7.8 Conclusions 166
References 167
8 Data Management in Fog Computing 171
Tina Samizadeh Nikoui, Amir Masoud Rahmani, and Hooman Tabarsaied
8.1 Introduction 171
8.2 Background 172
8.3 Fog Data Management 174
8.4 Future Research and Direction 186
8.5 Conclusions 186
References 188
9 Predictive Analysis to Support Fog Application Deployment 191
Antonio Brogi, Stefano Forti, and Ahmad Ibrahim
9.1 Introduction 191
9.2 Motivating Example: Smart Building 193
9.3 Predictive Analysis with Fog Torch 197
9.4 Motivating Example (continued) 206
9.5 Related Work 207
9.6 Future Research Directions 214
9.7 Conclusions 216
References 217
10 Using Machine Learning for Protecting the Security and Privacy of Internet of Things (Io T) Systems 223
Melody Moh and Robinson Raju
10.1 Introduction 223
10.2 Background 234
10.3 Survey of ML Techniques for Defending Io T Devices 242
10.4 Machine Learning in Fog Computing 248
10.4.1 Introduction 248
10.5 Future Research Directions 252
10.6 Conclusions 252
References 253
Part III Applications and Issues 259
11 Fog Computing Realization for Big Data Analytics 261
Farhad Mehdipour, Bahman Javadi, Aniket Mahanti, and Guillermo Ramirez-Prado
11.1 Introduction 261
11.2 Big Data Analytics 262
11.3 Data Analytics in the Fog 267
11.4 Prototypes and Evaluation 272
11.4.1 Architecture 272
11.4.2 Configurations 274
11.5 Case Studies 277
11.6 Related Work 282
11.7 Future Research Directions 287
11.8 Conclusions 287
References 288
12 Exploiting Fog Computing in Health Monitoring 291
Tuan Nguyen Gia and Mingzhe Jiang
12.1 Introduction 291
12.2 An Architecture of a Health Monitoring Io T-Based System with Fog Computing 293
12.3 Fog Computing Services in Smart E-Health Gateways 297
12.4 System Implementation 304
12.5 Case Studies, Experimental Results, and Evaluation 308
12.6 Discussion of Connected Components 313
12.7 Related Applications in Fog Computing 313
12.8 Future Research Directions 314
12.9 Conclusions 314
References 315
13 Smart Surveillance Video Stream Processing at the Edge for Real-Time Human Objects Tracking 319
Seyed Yahya Nikouei, Ronghua Xu, and Yu Chen
13.1 Introduction 319
13.2 Human Object Detection 320
13.3 Object Tracking 327
13.4 Lightweight Human Detection 335
13.5 Case Study 337
13.6 Future Research Directions 342
13.7 Conclusions 343
References 343
14 Fog Computing Model for Evolving Smart Transportation Applications 347
M. Muzakkir Hussain, Mohammad Saad Alam, and M.M. Sufyan Beg
14.1 Introduction 347
14.2 Data-Driven Intelligent Transportation Systems 348
14.3 Mission-Critical Computing Requirements of Smart Transportation Applications 351
14.4 Fog Computing for Smart Transportation Applications 354
14.5 Case Study: Intelligent Traffic Lights Management (ITLM) System 359
14.6 Fog Orchestration Challenges and Future Directions 362
14.7 Future Research Directions 364
14.8 Conclusions 369
References 370
15 Testing Perspectives of Fog-Based Io T Applications 373
Priyanka Chawla and Rohit Chawla
15.1 Introduction 373
15.2 Background 374
15.3 Testing Perspectives 376
15.4 Future Research Directions 393
15.5 Conclusions 405
References 406
16 Legal Aspects of Operating Io T Applications in the Fog 411
G. Gultekin Varkonyi, Sz. Varadi, and Attila Kertesz
16.1 Introduction 411
16.2 Related Work 412
16.3 Classification of Fog/Edge/Io T Applications 413
16.4 Restrictions of the GDPR Affecting Cloud, Fog, and Io T Applications 414
16.5 Data Protection by Design Principles 425
16.6 Future Research Directions 430
16.7 Conclusions 430
Acknowledgment 431
References 431
17 Modeling and Simulation of Fog and Edge Computing Environments Using i Fog Sim Toolkit 433
Redowan Mahmud and Rajkumar Buyya
17.1 Introduction 433
17.2 i Fog Sim Simulator and Its Components 435
17.3 Installation of i Fog Sim 436
17.4 Building Simulation with i Fog Sim 437
17.5 Example Scenarios 438
17.6 Simulation of a Placement Policy 450
17.7 A Case Study in Smart Healthcare 461
17.8 Conclusions 463
References 464
Index 467
Circa l’autore
Rajkumar Buyya, Ph D, is Redmond Barry Distinguished Professor and Director of the Cloud Computing and Distributed Systems Laboratory, University of Melbourne, Australia and founding CEO of Manjrasoft. Dr. Buyya is author of several works including Mastering Cloud Computing and Editor-in-Chief of Wiley Software: Practice and Experience Journal.
Satish Narayana Srirama, Ph D, is a Research Professor and head of the Mobile & Cloud Lab, Institute of Computer Science, University of Tartu, Estonia. He is editor of Wiley Software: Practice and Experience Journal and has co-authored over 120 scientific publications.