IoT-enabled Smart Healthcare Systems, Services and Applications

1 Cover

2 Title Page

3 Copyright Page

4 Preface

5 Acknowledgments

6 About the Editors

7 List of Contributors

8 1 The Role of Emerging Technologies in Smart Healthcare 1.1 Introduction 1.2 Emerging Technologies in Smart Healthcare 1.3 Realization of SHC through Emerging Technologies (Applications) 1.4 Conclusion Author Biography References

9 2 ICN‐Fog Computing for IoT‐Based Healthcare: 2.1 Introduction 2.2 ICN in IoT 2.3 IoT in Healthcare 2.4 Role of Fog Computing in IoT 2.5 Fog Computing in Healthcare: A Classification Approach 2.6 ICN‐Fog Leveraging Healthcare Architecture 2.7 Challenges in the Healthcare System 2.8 Conclusion References

10 3 Internet of Things (IoT) Enabled Software Defined Networking (SDN) for Load Balancing, Edge, Cloud Computing in Healthcare 3.1 Overview of Software‐Defined Networking 3.2 Overview of Healthcare 3.3 Technologies Used in Software‐Defined Networking (SDN) and HealthCare 3.4 Use Cases of Software‐Defined Networking in Healthcare 3.5 Research Directions 3.6 Conclusion Key Points Author Biography References

11 4 Security and Privacy Issues in Smart Healthcare System Using Internet of Things 4.1 Introduction 4.2 Overview of Internet of Things in Smart Healthcare Systems 4.3 Policies and Legislation Related to Smart Healthcare 4.4 Security and Privacy Issues in Smart Healthcare Based on Internet of Things 4.5 Issues in Location Privacy 4.6 Issues in Privacy of Stored Data and Threats Identity 4.7 Conclusion Author Biography References

12 5 An Overview of Architecture and Applications of IoT‐Based Health Care Systems 5.1 Introduction 5.2 Overview of the Healthcare System 5.3 Working Prototype of Healthcare System Using BAN 5.4 On‐Body Sensors and Sensor Embodiment 5.5 Vital Signs Monitoring 5.6 Biosensors in M‐Health 5.7 IoT‐Based Rehabilitation System 5.8 Future Work 5.9 Conclusion Authors' Biography References

13 6 A Review of e‐Healthcare System of India and Thailand 6.1 Introduction 6.2 Literature Review 6.3 Problem Statement 6.4 Methodology 6.5 Discussion 6.6 Conclusion References

14 7 WSN‐ and IoT‐Based Smart Surveillance Systems for Patients with Closed‐Loop Alarm 7.1 Introduction 7.2 Literature Review 7.3 Proposed Work: WSN and IoT‐Based Smart Surveillance System for Patients with Closed‐Loop Alarm 7.4 Implementation and Evaluation of the WSN and IoT‐Based Smart Surveillance System for Patients with Closed‐Loop Alarm 7.5 Conclusion and Future Work References

15 8 An IoMT ‐Based Smart Remote Monitoring System for Healthcare 8.1 Introduction 8.2 Literature Review 8.3 Methodology 8.4 Use Case of Real‐Time Remote Monitoring System 8.5 Conclusion References

16 9 A Multi‐Domain Perspective of Future Directions for VANETs for Emergency Message Dissemination 9.1 Introduction 9.2 Future Directions of Multi‐Domain VANETs Emergency Message Dissemination 9.3 Role of VANETs in Healthcare Systems 9.4 Techniques Used for Fast Delivery of Emergency Message in VANETs to Help the Healthcare System 9.5 Current Facilities and Limitations for Implementing the Real‐Time Environment 9.6 Discussion on Upcoming Trends and Possibilities with Future Readings 9.7 Conclusion Author Biography References

17 Index

18 End User License Agreement

1 Chapter 4Table 4.1 FISMA laws.

2 Chapter 5Table 5.1 Comparison table of gas sensors and its concepts.Table 5.2 Heart rate comparison table.

3 Chapter 6Table 6.1 Difference between health facilities in rural and urban India [41...

4 Chapter 9Table 9.1 Limitations of VANETs with (a) IoT being an IoV, (b) fog computin...

1 Chapter 1 Figure 1.1 OECD countries, science and technology.

2 Chapter 2 Figure 2.1 NDN hourglass architecture. Figure 2.2 NDN packet format. Figure 2.3 IoT in healthcare. Figure 2.4 Fog computing in IoT. Figure 2.5 ICN‐Fog computing in healthcare.

3 Chapter 3Figure 3.1 Technologies of SDN in healthcare.Figure 3.2 SDN‐IoT based on healthcare network.Figure 3.3 Edge based on SDN in e‐healthcare.Figure 3.4 Architecture of load balancing in SDN healthcare.Figure 3.5 Software‐defined networking in healthcare.

4 Chapter 4Figure 4.1 Architecture of Smart HealthCare System (SHC).

5 Chapter 5Figure 5.1 Architecture of health care system.Figure 5.2 Working flow of health care system.Figure 5.3 Raspberry Pi module.Figure 5.4 Integrating IOT ecosystem.Figure 5.5 Schematic diagram of gas sensor.Figure 5.6 Segments of bio‐chemical sensor.Figure 5.7 Wireless sensor network architecture.Figure 5.8 Readings of pulse oximetry.Figure 5.9 Working of blood pressure sensor.Figure 5.10 Measurement of respiration rate.Figure 5.11 Measuring body temperature.Figure 5.12 Schematic diagram of CGM.Figure 5.13 Bio sensors‐ bio signals to electric signals.Figure 5.14 Block diagram of IOT rehabilitation system.Figure 5.15 Framework of rehabilitation system methodology.Figure 5.16 Services and applications of IOT.

6 Chapter 6Figure 6.1 Number of publications of India and Thailand on e healthcare syst...Figure 6.2 Number of publication on rural e‐healthcare system in India and T...Figure 6.3 Number of publication on technology used in e‐healthcare system o...Figure 6.4 Number of publication on cost‐effectiveness of e‐healthcare syste...

7 Chapter 7Figure 7.1 Working of IoT.Figure 7.2 Wireless sensor network.Figure 7.3 Underground WSNs.Figure 7.4 Underwater WSNs.Figure 7.5 Multimedia WSNs.Figure 7.6 Applications of wireless sensor networks.Figure 7.7 Sensors used in experiments.Figure 7.8 The proposed model architecture.Figure 7.9 Methodology flowchart.Figure 7.10 Channel details.Figure 7.11 Raw data.Figure 7.12 Link to read a channel feed [28].Figure 7.13 WeMos D1 mini – Mini NodeMcu [29].Figure 7.14 Ardunio IDE software [30].Figure 7.15 ThingSpeak IoT platform [31].Figure 7.16 Connection architecture of all the components.Figure 7.17 MAX30102 pulse oximeter/heart‐rate sensor.Figure 7.18 MAX30102 pulse oximeter sensor data in Arduino IDE.Figure 7.19 Pulse sensor.Figure 7.20 Pulse sensor data in Arduino IDE.Figure 7.21 Accelerometer sensor.Figure 7.22 Accelerometer data in Arduino IDE.Figure 7.23 MAX6675 sensor data in Arduino IDE.Figure 7.24 MAX6675 sensor data in Arduino IDE.Figure 7.25 MAX30102 pulse oximeter sensor data in ThingSpeak.Figure 7.26 Temperature sensor data in ThingSpeak.Figure 7.27 (a) Data of accelerometer of x‐axis sent in ThingSpeak. (b) Data...Figure 7.28 Pulse sensor data in ThingSpeak.Figure 7.29 Sign‐In/‐Up interface.Figure 7.30 Patients data in Android application.Figure 7.31 Patients data with alert.

8 Chapter 8Figure 8.1 Different types of cancer cases found in the world in 2018.Figure 8.2 Cervical cancer cases and deaths depending on the HDI value of co...Figure 8.3 Proposed methodology for IoMT‐based smart remote monitoring syste...Figure 8.4 Automated IoT‐based image acquisition process.Figure 8.5 An IoMT‐based smart remote monitoring system for cervix cancer.

9 Chapter 9Figure 9.1 Applications are defined. There are five text documents that expl...Figure 9.2 Diagrammatic representation of multi‐domain future perspective of...Figure 9.3 Diagrammatic representation of multi‐domain future perspective of...Figure 9.4 Emerging research directions in VANETs with multi‐domain perspect...

1 Cover Page

2 Title Page

3 Copyright Page

4 Preface

5 Acknowledgments

6 About the Editors

7 List of Contributors

8 Table of Contents

9 Begin Reading

10 Index

11 Wiley End User License Agreement

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