Mauri Kuorilehto, Mikko Kohvakka, Jukka Suhonen, Panu Hämäläinen, Marko Hännikäinen, Timo D. Hamalainen
Ultra-Low Energy Wireless Sensor Networks in Practice (eBook, PDF)
Theory, Realization and Deployment
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Mauri Kuorilehto, Mikko Kohvakka, Jukka Suhonen, Panu Hämäläinen, Marko Hännikäinen, Timo D. Hamalainen
Ultra-Low Energy Wireless Sensor Networks in Practice (eBook, PDF)
Theory, Realization and Deployment
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Finally a book on Wireless Sensor Networks that covers real world applications and contains practical advice! Kuorilehto et al. have written the first practical guide to wireless sensor networks. The authors draw on their experience in the development and field-testing of autonomous wireless sensor networks (WSNs) to offer a comprehensive reference on fundamentals, practical matters, limitations and solutions of this fast moving research area. Ultra Low Energy Wireless Sensor Networks in Practice: * Explains the essential problems and issues in real wireless sensor networks, and analyzes the…mehr
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Finally a book on Wireless Sensor Networks that covers real world applications and contains practical advice! Kuorilehto et al. have written the first practical guide to wireless sensor networks. The authors draw on their experience in the development and field-testing of autonomous wireless sensor networks (WSNs) to offer a comprehensive reference on fundamentals, practical matters, limitations and solutions of this fast moving research area. Ultra Low Energy Wireless Sensor Networks in Practice: * Explains the essential problems and issues in real wireless sensor networks, and analyzes the most promising solutions. * Provides a comprehensive guide to applications, functionality, protocols, and algorithms for WSNs. * Offers practical experiences from new applications and their field-testing, including several deployed networks. * Includes simulations and physical measurements for energy consumption, bit rate, latency, memory, and lifetime. * Covers embedded resource-limited operating systems, middleware and application software. Ultra Low Energy Wireless Sensor Networks in Practice will prove essential reading for Research Scientists, advanced students in Networking, Electrical Engineering and Computer Science as well as Product Managers and Design Engineers.
Produktdetails
- Produktdetails
- Verlag: John Wiley & Sons
- Seitenzahl: 396
- Erscheinungstermin: 2. August 2008
- Englisch
- ISBN-13: 9780470516799
- Artikelnr.: 37296434
- Verlag: John Wiley & Sons
- Seitenzahl: 396
- Erscheinungstermin: 2. August 2008
- Englisch
- ISBN-13: 9780470516799
- Artikelnr.: 37296434
Timo D. Hämäläinen is Professor and Institute Vice President at Tampere University of Technology, Finland. Timo acted as a senior research scientist and project manager at TUT from 1997-2001. In 2001 he was nominated full professor at TUT/Institute of Digital and Computer Systems. He heads the DACI research group that focuses on three main lines: wireless local area networking and wireless sensor networks, high-performance DSP/HW based video encoding, and interconnection networks with design flow tools for heterogeneous SoC platforms. He has published over 30 refereed international journals and over 150 conference publications. Marko Hännikäinen is Senior Research Scientist and Mauri Kuorilehto, Mikko Kohvakka, Jukka Suhonen, Panu Hämäläinen are all Research Scientists at Tampere University of Technology, Finland.
Preface. List of Abbreviations. PART I. INTRODUCTION. 1. Introduction. 1.1 Overview of Wireless Technologies. 1.2 TUTWSN. 1.3 Contents of the Book . PART II. DESIGN SPACE OF WSNS. 2. WSN Properties. 2.1 Characteristics of WSNs. 2.2 WSN Applications. 2.3 Requirements for WSNs. 3. Standards and Proposals. 3.1 Standards. 3.2 Variations of Standards. 4. Sensor Node Platforms. 4.1 Platform Components. 4.2 Existing Platforms. 4.3 TUTWSN Platforms. 4.4 Antenna Design. 5. Design of WSNs. 5.1 Design Dimensions. 5.2 WSN Design Flow. 5.3 Related Research on WSN Design. 5.4 WSN Evaluation Methods. 5.5 WSN Evaluation Tools. PART III. WSN PROTOCOL STACK. 6. Protocol Stack Overview. 6.1 Outline of WSN Stack. 7. MAC Protocols. 7.1 Requirements. 7.2 General MAC Approaches. 7.3 WSN MAC Protocols. 8. Routing Protocols. 8.1 Requirements. 8.2 Classifications. 8.3 Operation Principles. 8.4 Summary. 9. Middleware and Application Layer. 9.1 Motivation and Requirements. 9.2 WSN Middleware Approaches. 9.3 WSN Middleware Proposals. 10. Operating Systems. 10.1 Motivation and Requirements. 10.2 Existing OSs. 11. QoS Issues in WSN. 11.1 Traditional QoS. 11.2 Unique Requirements in WSNs. 11.3 Parameters Defining WSN QoS. 11.4 QoS Support in Protocol Layers. 11.5 Summary. 12. Security in WSNs. 12.1 WSN Security Threats and Countermeasures. 12.2 Security Architectures for WSNs. 12.3 Key Distribution in WSNs. 12.4 Summary of WSN Security Considerations. PART IV. TUTWSN. 13. TUTWSN MAC Protocol. 13.1 Network Topology. 13.2 Channel Access. 13.3 Frequency Division. 13.4 Advanced Mobility Support. 13.5 Advanced Support for Bursty Traffic. 13.6 TUTWSN MAC Optimization. 13.7 TUTWSN MAC Implementation. 13.8 Measured Performance of TUTWSN MAC. 14. TUTWSN Routing Protocol. 14.1 Design and Implementation. 14.2 Related Work. 14.3 Cost-Aware Routing. 14.4 Implementation. 14.5 Measurement Results. 15. TUTWSN API. 15.1 Design of TUTWSN API. 15.2 TUTWSN API Implementation. 15.3 TUTWSN API Evaluation. 16. TUTWSN SensorOS. 16.1 SensorOS Design. 16.2 SensorOS Implementation. 16.3 SensorOS Performance Evaluation. 16.4 Lightweight Kernel Configuration. 16.5 SensorOS Bootloader Service. 17. Cross-layer Issues in TUTWSN. 17.1 Cross-layer Node Configuration. 17.2 Piggybacking Data. 17.3 Self-configuration with Cross-layer Information. 18. Protocol Analysis Models. 18.1 PHY Power Analysis. 18.2 Radio Energy Models. 18.3 Contention Models. 18.4 Node Operation Models. 18.5 Summary. 19. WISENES Design and Evaluation Environment. 19.1 Features. 19.2 WSN Design with WISENES. 19.3 WISENES Framework. 19.4 Existing WISENES Designs. 19.5 WISENES Simulation Results. PART V. DEPLOYMENT. 20. TUTWSN Deployments. 20.1 TUTWSN Deployment Architecture. 20.2 Network Self-diagnostics. 20.3 Security Experiments. 21. Sensing Applications. 21.1 Linear-position Metering. 21.1.3 Results. 21.2 Indoor-temperature Sensing. 21.3 Environmental Monitoring. 22. Transfer Applications. 22.1 TCP/IP for TUTWSN. 22.2 Realtime High-performance WSN. 23. Tracking Applications. 23.1 Surveillance System. 23.2 Indoor Positioning. 23.3 Team Game Management. PART VI. CONCLUSIONS. 24. Conclusions. References. Index.
Preface I INTRODUCTION 1 Introduction 1.1 TUTWSN 1.2 Contents of the Book
II DESIGN SPACE OF WSNS 2 WSN Properties 2.1 Characteristics of WSNs 2.2
WSN Applications 2.3 Requirements for WSNs 3 Standards and Proposals 3.1
Standards 3.2 Variations of Standards 4 Sensor Node Platforms 4.1 Platform
Components 4.2 Existing Platforms 4.3 TUTWSN Platforms 4.4 Antenna Design 5
Design of WSNs 5.1 Design Dimensions 5.2 WSN Design Flow 5.3 Related
Research on WSN Design 5.4 WSN Evaluation Methods 5.5 WSN Evaluation Tools
III WSN PROTOCOL STACK 6 Protocol Stack Overview 6.1 Outline of WSN Stack 7
MAC Protocols 7.1 Requirements 7.2 General Medium Access Control (MAC)
Approaches 7.3 WSN MAC Protocols 8 Routing Protocols 8.1 Requirements 8.2
Classifications 8.3 Operation Principles 8.4 Summary 9 Middleware and
Application Layer 9.1 Motivation and Requirements 9.2 WSN Middleware
Approaches 9.3 WSN Middleware Proposals 10 Operating Systems 10.1
Motivation and Requirements 10.2 Existing OSs 11 QoS Issues in WSN 11.1
Traditional QoS 11.2 Unique Requirements in WSNs 11.3 Parameters Defining
WSN QoS 11.4 QoS Support in Protocol Layers 11.5 Summary 12 Security in
WSNs 12.1 WSN Security Threats and Countermeasures 12.2 Security
Architectures for WSNs 12.3 Key Distribution in WSNs 12.4 Summary of WSN
Security Considerations IV TUTWSN 13 TUTWSN MAC Protocol 13.1 Network
Topology 13.2 Channel Access 13.3 Frequency Division 13.4 Advanced Mobility
Support 13.5 Advanced Support for Bursty Traffic 13.6 TUTWSN MAC
Optimization 13.6.1 Reducing radio requirements 13.6.2 Network beacon rate
optimization 13.7 TUTWSN MAC Implementation 13.8 Measured Performance of
TUTWSN MAC 14 TUTWSN Routing Protocol 14.1 Design and Implementation 14.2
Related Work 14.3 Cost-Aware Routing 14.4 Implementation 14.5 Measurement
Results 15 TUTWSN API 15.1 Design of TUTWSN API 15.2 TUTWSN API
Implementation 15.3 TUTWSN API Evaluation 16 TUTWSN SensorOS 16.1 SensorOS
Design 16.2 SensorOS Implementation 16.3 SensorOS Performance Evaluation
16.4 Lightweight Kernel Configuration 16.5 SensorOS Bootloader Service 17
Cross-Layer Issues in TUTWSN 213 17.1 Cross-layer Node Configuration 17.2
Piggybacking Data 17.3 Self-configuration with Cross-layer Information 18
Protocol Analysis Models 18.1 PHY Power Analysis 18.2 Radio Energy Models
18.3 Contention Models 18.4 Node Operation Models 18.5 Summary 19 WISENES
Design and Evaluation Environment 19.1 Features 19.2 WSN Design with
WISENES 19.3 WISENES Framework 19.4 Existing WISENES Designs 19.5 WISENES
Simulation Results V DEPLOYMENT 20 TUTWSN Deployments 20.1 TUTWSN
Deployment Architecture 20.2 Network Self-diagnostics 20.3 Security
Experiments 21 Sensing Applications 21.1 Linear Position Metering 21.2
Indoor Temperature Sensing 21.3 Environmental Monitoring 22 Transfer
Applications 22.1 TCP/IP for TUTWSN 22.2 Real-time High-performance WSN 23
Tracking Applications 23.1 Surveillance System 23.2 Indoor Positioning 23.3
Team Game Management VI CONCLUSIONS 24 Conclusions Bibliography
II DESIGN SPACE OF WSNS 2 WSN Properties 2.1 Characteristics of WSNs 2.2
WSN Applications 2.3 Requirements for WSNs 3 Standards and Proposals 3.1
Standards 3.2 Variations of Standards 4 Sensor Node Platforms 4.1 Platform
Components 4.2 Existing Platforms 4.3 TUTWSN Platforms 4.4 Antenna Design 5
Design of WSNs 5.1 Design Dimensions 5.2 WSN Design Flow 5.3 Related
Research on WSN Design 5.4 WSN Evaluation Methods 5.5 WSN Evaluation Tools
III WSN PROTOCOL STACK 6 Protocol Stack Overview 6.1 Outline of WSN Stack 7
MAC Protocols 7.1 Requirements 7.2 General Medium Access Control (MAC)
Approaches 7.3 WSN MAC Protocols 8 Routing Protocols 8.1 Requirements 8.2
Classifications 8.3 Operation Principles 8.4 Summary 9 Middleware and
Application Layer 9.1 Motivation and Requirements 9.2 WSN Middleware
Approaches 9.3 WSN Middleware Proposals 10 Operating Systems 10.1
Motivation and Requirements 10.2 Existing OSs 11 QoS Issues in WSN 11.1
Traditional QoS 11.2 Unique Requirements in WSNs 11.3 Parameters Defining
WSN QoS 11.4 QoS Support in Protocol Layers 11.5 Summary 12 Security in
WSNs 12.1 WSN Security Threats and Countermeasures 12.2 Security
Architectures for WSNs 12.3 Key Distribution in WSNs 12.4 Summary of WSN
Security Considerations IV TUTWSN 13 TUTWSN MAC Protocol 13.1 Network
Topology 13.2 Channel Access 13.3 Frequency Division 13.4 Advanced Mobility
Support 13.5 Advanced Support for Bursty Traffic 13.6 TUTWSN MAC
Optimization 13.6.1 Reducing radio requirements 13.6.2 Network beacon rate
optimization 13.7 TUTWSN MAC Implementation 13.8 Measured Performance of
TUTWSN MAC 14 TUTWSN Routing Protocol 14.1 Design and Implementation 14.2
Related Work 14.3 Cost-Aware Routing 14.4 Implementation 14.5 Measurement
Results 15 TUTWSN API 15.1 Design of TUTWSN API 15.2 TUTWSN API
Implementation 15.3 TUTWSN API Evaluation 16 TUTWSN SensorOS 16.1 SensorOS
Design 16.2 SensorOS Implementation 16.3 SensorOS Performance Evaluation
16.4 Lightweight Kernel Configuration 16.5 SensorOS Bootloader Service 17
Cross-Layer Issues in TUTWSN 213 17.1 Cross-layer Node Configuration 17.2
Piggybacking Data 17.3 Self-configuration with Cross-layer Information 18
Protocol Analysis Models 18.1 PHY Power Analysis 18.2 Radio Energy Models
18.3 Contention Models 18.4 Node Operation Models 18.5 Summary 19 WISENES
Design and Evaluation Environment 19.1 Features 19.2 WSN Design with
WISENES 19.3 WISENES Framework 19.4 Existing WISENES Designs 19.5 WISENES
Simulation Results V DEPLOYMENT 20 TUTWSN Deployments 20.1 TUTWSN
Deployment Architecture 20.2 Network Self-diagnostics 20.3 Security
Experiments 21 Sensing Applications 21.1 Linear Position Metering 21.2
Indoor Temperature Sensing 21.3 Environmental Monitoring 22 Transfer
Applications 22.1 TCP/IP for TUTWSN 22.2 Real-time High-performance WSN 23
Tracking Applications 23.1 Surveillance System 23.2 Indoor Positioning 23.3
Team Game Management VI CONCLUSIONS 24 Conclusions Bibliography
Preface. List of Abbreviations. PART I. INTRODUCTION. 1. Introduction. 1.1 Overview of Wireless Technologies. 1.2 TUTWSN. 1.3 Contents of the Book . PART II. DESIGN SPACE OF WSNS. 2. WSN Properties. 2.1 Characteristics of WSNs. 2.2 WSN Applications. 2.3 Requirements for WSNs. 3. Standards and Proposals. 3.1 Standards. 3.2 Variations of Standards. 4. Sensor Node Platforms. 4.1 Platform Components. 4.2 Existing Platforms. 4.3 TUTWSN Platforms. 4.4 Antenna Design. 5. Design of WSNs. 5.1 Design Dimensions. 5.2 WSN Design Flow. 5.3 Related Research on WSN Design. 5.4 WSN Evaluation Methods. 5.5 WSN Evaluation Tools. PART III. WSN PROTOCOL STACK. 6. Protocol Stack Overview. 6.1 Outline of WSN Stack. 7. MAC Protocols. 7.1 Requirements. 7.2 General MAC Approaches. 7.3 WSN MAC Protocols. 8. Routing Protocols. 8.1 Requirements. 8.2 Classifications. 8.3 Operation Principles. 8.4 Summary. 9. Middleware and Application Layer. 9.1 Motivation and Requirements. 9.2 WSN Middleware Approaches. 9.3 WSN Middleware Proposals. 10. Operating Systems. 10.1 Motivation and Requirements. 10.2 Existing OSs. 11. QoS Issues in WSN. 11.1 Traditional QoS. 11.2 Unique Requirements in WSNs. 11.3 Parameters Defining WSN QoS. 11.4 QoS Support in Protocol Layers. 11.5 Summary. 12. Security in WSNs. 12.1 WSN Security Threats and Countermeasures. 12.2 Security Architectures for WSNs. 12.3 Key Distribution in WSNs. 12.4 Summary of WSN Security Considerations. PART IV. TUTWSN. 13. TUTWSN MAC Protocol. 13.1 Network Topology. 13.2 Channel Access. 13.3 Frequency Division. 13.4 Advanced Mobility Support. 13.5 Advanced Support for Bursty Traffic. 13.6 TUTWSN MAC Optimization. 13.7 TUTWSN MAC Implementation. 13.8 Measured Performance of TUTWSN MAC. 14. TUTWSN Routing Protocol. 14.1 Design and Implementation. 14.2 Related Work. 14.3 Cost-Aware Routing. 14.4 Implementation. 14.5 Measurement Results. 15. TUTWSN API. 15.1 Design of TUTWSN API. 15.2 TUTWSN API Implementation. 15.3 TUTWSN API Evaluation. 16. TUTWSN SensorOS. 16.1 SensorOS Design. 16.2 SensorOS Implementation. 16.3 SensorOS Performance Evaluation. 16.4 Lightweight Kernel Configuration. 16.5 SensorOS Bootloader Service. 17. Cross-layer Issues in TUTWSN. 17.1 Cross-layer Node Configuration. 17.2 Piggybacking Data. 17.3 Self-configuration with Cross-layer Information. 18. Protocol Analysis Models. 18.1 PHY Power Analysis. 18.2 Radio Energy Models. 18.3 Contention Models. 18.4 Node Operation Models. 18.5 Summary. 19. WISENES Design and Evaluation Environment. 19.1 Features. 19.2 WSN Design with WISENES. 19.3 WISENES Framework. 19.4 Existing WISENES Designs. 19.5 WISENES Simulation Results. PART V. DEPLOYMENT. 20. TUTWSN Deployments. 20.1 TUTWSN Deployment Architecture. 20.2 Network Self-diagnostics. 20.3 Security Experiments. 21. Sensing Applications. 21.1 Linear-position Metering. 21.1.3 Results. 21.2 Indoor-temperature Sensing. 21.3 Environmental Monitoring. 22. Transfer Applications. 22.1 TCP/IP for TUTWSN. 22.2 Realtime High-performance WSN. 23. Tracking Applications. 23.1 Surveillance System. 23.2 Indoor Positioning. 23.3 Team Game Management. PART VI. CONCLUSIONS. 24. Conclusions. References. Index.
Preface I INTRODUCTION 1 Introduction 1.1 TUTWSN 1.2 Contents of the Book
II DESIGN SPACE OF WSNS 2 WSN Properties 2.1 Characteristics of WSNs 2.2
WSN Applications 2.3 Requirements for WSNs 3 Standards and Proposals 3.1
Standards 3.2 Variations of Standards 4 Sensor Node Platforms 4.1 Platform
Components 4.2 Existing Platforms 4.3 TUTWSN Platforms 4.4 Antenna Design 5
Design of WSNs 5.1 Design Dimensions 5.2 WSN Design Flow 5.3 Related
Research on WSN Design 5.4 WSN Evaluation Methods 5.5 WSN Evaluation Tools
III WSN PROTOCOL STACK 6 Protocol Stack Overview 6.1 Outline of WSN Stack 7
MAC Protocols 7.1 Requirements 7.2 General Medium Access Control (MAC)
Approaches 7.3 WSN MAC Protocols 8 Routing Protocols 8.1 Requirements 8.2
Classifications 8.3 Operation Principles 8.4 Summary 9 Middleware and
Application Layer 9.1 Motivation and Requirements 9.2 WSN Middleware
Approaches 9.3 WSN Middleware Proposals 10 Operating Systems 10.1
Motivation and Requirements 10.2 Existing OSs 11 QoS Issues in WSN 11.1
Traditional QoS 11.2 Unique Requirements in WSNs 11.3 Parameters Defining
WSN QoS 11.4 QoS Support in Protocol Layers 11.5 Summary 12 Security in
WSNs 12.1 WSN Security Threats and Countermeasures 12.2 Security
Architectures for WSNs 12.3 Key Distribution in WSNs 12.4 Summary of WSN
Security Considerations IV TUTWSN 13 TUTWSN MAC Protocol 13.1 Network
Topology 13.2 Channel Access 13.3 Frequency Division 13.4 Advanced Mobility
Support 13.5 Advanced Support for Bursty Traffic 13.6 TUTWSN MAC
Optimization 13.6.1 Reducing radio requirements 13.6.2 Network beacon rate
optimization 13.7 TUTWSN MAC Implementation 13.8 Measured Performance of
TUTWSN MAC 14 TUTWSN Routing Protocol 14.1 Design and Implementation 14.2
Related Work 14.3 Cost-Aware Routing 14.4 Implementation 14.5 Measurement
Results 15 TUTWSN API 15.1 Design of TUTWSN API 15.2 TUTWSN API
Implementation 15.3 TUTWSN API Evaluation 16 TUTWSN SensorOS 16.1 SensorOS
Design 16.2 SensorOS Implementation 16.3 SensorOS Performance Evaluation
16.4 Lightweight Kernel Configuration 16.5 SensorOS Bootloader Service 17
Cross-Layer Issues in TUTWSN 213 17.1 Cross-layer Node Configuration 17.2
Piggybacking Data 17.3 Self-configuration with Cross-layer Information 18
Protocol Analysis Models 18.1 PHY Power Analysis 18.2 Radio Energy Models
18.3 Contention Models 18.4 Node Operation Models 18.5 Summary 19 WISENES
Design and Evaluation Environment 19.1 Features 19.2 WSN Design with
WISENES 19.3 WISENES Framework 19.4 Existing WISENES Designs 19.5 WISENES
Simulation Results V DEPLOYMENT 20 TUTWSN Deployments 20.1 TUTWSN
Deployment Architecture 20.2 Network Self-diagnostics 20.3 Security
Experiments 21 Sensing Applications 21.1 Linear Position Metering 21.2
Indoor Temperature Sensing 21.3 Environmental Monitoring 22 Transfer
Applications 22.1 TCP/IP for TUTWSN 22.2 Real-time High-performance WSN 23
Tracking Applications 23.1 Surveillance System 23.2 Indoor Positioning 23.3
Team Game Management VI CONCLUSIONS 24 Conclusions Bibliography
II DESIGN SPACE OF WSNS 2 WSN Properties 2.1 Characteristics of WSNs 2.2
WSN Applications 2.3 Requirements for WSNs 3 Standards and Proposals 3.1
Standards 3.2 Variations of Standards 4 Sensor Node Platforms 4.1 Platform
Components 4.2 Existing Platforms 4.3 TUTWSN Platforms 4.4 Antenna Design 5
Design of WSNs 5.1 Design Dimensions 5.2 WSN Design Flow 5.3 Related
Research on WSN Design 5.4 WSN Evaluation Methods 5.5 WSN Evaluation Tools
III WSN PROTOCOL STACK 6 Protocol Stack Overview 6.1 Outline of WSN Stack 7
MAC Protocols 7.1 Requirements 7.2 General Medium Access Control (MAC)
Approaches 7.3 WSN MAC Protocols 8 Routing Protocols 8.1 Requirements 8.2
Classifications 8.3 Operation Principles 8.4 Summary 9 Middleware and
Application Layer 9.1 Motivation and Requirements 9.2 WSN Middleware
Approaches 9.3 WSN Middleware Proposals 10 Operating Systems 10.1
Motivation and Requirements 10.2 Existing OSs 11 QoS Issues in WSN 11.1
Traditional QoS 11.2 Unique Requirements in WSNs 11.3 Parameters Defining
WSN QoS 11.4 QoS Support in Protocol Layers 11.5 Summary 12 Security in
WSNs 12.1 WSN Security Threats and Countermeasures 12.2 Security
Architectures for WSNs 12.3 Key Distribution in WSNs 12.4 Summary of WSN
Security Considerations IV TUTWSN 13 TUTWSN MAC Protocol 13.1 Network
Topology 13.2 Channel Access 13.3 Frequency Division 13.4 Advanced Mobility
Support 13.5 Advanced Support for Bursty Traffic 13.6 TUTWSN MAC
Optimization 13.6.1 Reducing radio requirements 13.6.2 Network beacon rate
optimization 13.7 TUTWSN MAC Implementation 13.8 Measured Performance of
TUTWSN MAC 14 TUTWSN Routing Protocol 14.1 Design and Implementation 14.2
Related Work 14.3 Cost-Aware Routing 14.4 Implementation 14.5 Measurement
Results 15 TUTWSN API 15.1 Design of TUTWSN API 15.2 TUTWSN API
Implementation 15.3 TUTWSN API Evaluation 16 TUTWSN SensorOS 16.1 SensorOS
Design 16.2 SensorOS Implementation 16.3 SensorOS Performance Evaluation
16.4 Lightweight Kernel Configuration 16.5 SensorOS Bootloader Service 17
Cross-Layer Issues in TUTWSN 213 17.1 Cross-layer Node Configuration 17.2
Piggybacking Data 17.3 Self-configuration with Cross-layer Information 18
Protocol Analysis Models 18.1 PHY Power Analysis 18.2 Radio Energy Models
18.3 Contention Models 18.4 Node Operation Models 18.5 Summary 19 WISENES
Design and Evaluation Environment 19.1 Features 19.2 WSN Design with
WISENES 19.3 WISENES Framework 19.4 Existing WISENES Designs 19.5 WISENES
Simulation Results V DEPLOYMENT 20 TUTWSN Deployments 20.1 TUTWSN
Deployment Architecture 20.2 Network Self-diagnostics 20.3 Security
Experiments 21 Sensing Applications 21.1 Linear Position Metering 21.2
Indoor Temperature Sensing 21.3 Environmental Monitoring 22 Transfer
Applications 22.1 TCP/IP for TUTWSN 22.2 Real-time High-performance WSN 23
Tracking Applications 23.1 Surveillance System 23.2 Indoor Positioning 23.3
Team Game Management VI CONCLUSIONS 24 Conclusions Bibliography