| Contents |
Cover; Half Title; Title Page; Copyright Page; Contents; Preface; 1 Introduction to IoT Systems; 1.1 Introduction; 1.2 Overview of IoT Applications; 1.2.1 Healthcare; 1.2.2 Utility Services; 1.2.3 Automotive/Vehicular IoT; 1.2.4 Smart Agriculture; 1.2.5 Smart City; 1.3 IoT System Architectures and Design Approaches; 1.4 IoT Standards; 1.5 Summary; 2 Big Data in IoT Systems; 2.1 Introduction; 2.1.1 The Digital Economy and Ubiquitous Computing Systems; 2.1.2 The Internet of Things; 2.2 Theoretical Approaches to UCS; 2.2.1 Category Theory; 2.2.2 Process Algebras |
| Contents |
2.3 Core Digital Technologies for UCS; 2.3.1 Semantic Technologies; 2.3.2 Cognitive Computing and Deep Learning; 2.4 Big Data and Its Sources; 2.4.1 Radio Frequency Identification; 2.4.2 Wireless Sensor Networks; 2.4.3 Machine-to-Machine Communications; 2.4.4 Cloud Computing; 2.5 Big Data in IoT Application Areas; 2.5.1 Healthcare Systems; 2.5.2 Food Supply Chains; 2.5.3 Smart Environment Domain; 2.5.3.1 Smart power system; 2.5.3.2 Smart home; 2.5.3.3 Smart environment control; 2.5.3.4 Safety and surveillance; 2.5.3.5 Smart city; 2.5.4 Safer Mining Production; 2.5.5 Transportation and Logistics |
| Contents |
2.5.6 Firefighting; 2.6 Challenges of Big Data in IoT Systems; 2.6.1 Big Data Mining; 2.6.2 Proposed Big Data Management and Analysis Techniques; 2.7 New Product Development and UCS; 2.8 Organizational and Policy Implications; 3 Basics of Communication Networks; 3.1 Introduction; 3.2 Basic Networking Techniques; 3.2.1 Network Architecture; 3.2.1.1 Wide area network; 3.2.1.2 Local area network; 3.2.1.3 Personal area network; 3.2.1.4 Infrastructure and ad hoc networks; 3.3 Packet Communication Protocols; 3.3.1 Communication Protocols/Software Models; 3.3.2 Data Link Layer Protocols |
| Contents |
3.3.2.1 LLC sublayer; 3.3.2.2 Forward error correction techniques; 3.3.2.3 MAC sublayer; 3.3.2.4 Static channelization: TDMA; 3.3.2.5 Dynamic medium access control techniques; 3.3.2.6 Polling access technique; 3.3.2.7 Random access technique; 3.3.2.8 Network protocols; 3.3.3 Transport Protocols; 3.4 Wireless Networking Basics; 3.4.1 Radio Propagation Environment; 3.5 Traffic Modeling; 3.6 Summary; 4 Low-Power Wide-Area Networks; 4.1 Introduction; 4.1.1 IoT Communication Requirements; 4.2 IoT Network Design Fundamentals; 4.3 LPWAN Standards; 4.3.1 Long-Range Wide-Area Network (LoRaWAN) |
| Contents |
4.3.2 SigFox; 4.4 Open Short-Range Networking Techniques; 4.4.1 IEEE802.11 Standards; 4.4.2 IEEE802.11ah Standard; 4.4.3 IEEE802.15.4 Standard; 4.4.4 Extension of the IEEE802.15.4 Standard; 4.5 A Heterogeneous IoT Network Architecture; 4.5.1 MFDRR Architecture; 4.5.2 The Blank Burst Algorithm; 4.6 Performance Evaluation of the Heterogeneous Network; 4.7 Conclusions; 5 Energy-Harvesting IoT Networks; 5.1 Review of Energy Harvesting Techniques; 5.1.1 Solar-Based Energy Harvesting Technique; 5.1.2 Thermal Energy Harvesting Technique; 5.1.3 Vibration-Based Energy Harvesting Technique |
| Abstract |
The Internet of Things (IoT) is one of the core technologies of current and future information and communications technology (ICT) sectors. IoT technologies will be deployed in numerous industries, including health, transport, smart cities, utility sectors, environment, security, and many other areas. In a manner suitable to a broad range of readers, this book introduces various key IoT technologies focusing on algorithms, process algebra, network architecture, energy harvesting, wireless communications, and network security. It presents IoT system design techniques, international IoT standards, and recent research outcomes relevant to the IoT system developments and provides existing and emerging solutions to the design and development of IoT platforms for multi-sector industries, particularly for Industry 4.0. The book also addresses some of the regulatory issues and design challenges related to IoT system deployments and proposes guidelines for possible future applications. |
| General note | 5.1.4 Radio Frequency (RF) Energy Harvesting Technique |
| Biographical note | Jamil Y. Khan received his PhD in electronic and electrical engineering from the University of Strathclyde, Glasgow, UK, in 1991. Since his PhD he has been working as an academic in the UK, New Zealand, and Australia. Currently, he is an associate professor in the School of Electrical Engineering and Computing, University of Newcastle, Australia. He leads a research group in telecommunication networks and IoT systems. Prof. Khan has published more than 180 international referred research papers and book chapters. He is a senior member of the IEEE and a member of the ACM. Mehmet R. Yuce received his PhD in electrical and computer engineering from North Carolina State University, Raleigh, USA, in 2004. He is an associate professor in the Department of Electrical and Computer Systems Engineering, Monash University, Australia. He has published more than 180 technical articles. His research interests include wearable devices and IoT for healthcare. He is a topical editor of The IEEE Sensors Journal and editor-in-chief of Sensors. |
| Source of description | Print version record. |
| Issued in other form | Print version: Khan, Jamil Y. Internet of Things (IoT) : Systems and Applications. Milton : Pan Stanford Publishing, ©2019 9789814800297 |
| Genre/form | Electronic books. |
| ISBN | 9780429678059 |
| ISBN | 0429678053 |
| ISBN | 9780429399084 (electronic bk.) |
| ISBN | 0429399081 (electronic bk.) |
| ISBN | 9780429678042 (electronic bk. ; EPUB) |
| ISBN | 0429678045 (electronic bk. ; EPUB) |
| ISBN | 9780429678035 (electronic bk. ; Mobipocket) |
| ISBN | 0429678037 (electronic bk. ; Mobipocket) |
| Stock number | 9780429399084 Taylor & Francis |
