Mobile AD HOC Networking : Cutting edge Directions
Basagni, Stefano
Mobile AD HOC Networking : Cutting edge Directions - 2nd - New Delhi Wiley India 2013 - 864p.
Part I General Issues
1 Multihop Ad Hoc Networking: The Evolutionary Path
1.1 Introduction
1.2 MANET Research: Major Achievements and Lessons Learned
1.3 Multihop Ad Hoc Networks: From Theory to Reality
1.4 Summary and Conclusions
2 Enabling Technologies and Standards for Mobile Multihop Wireless Networking
2.1 Introduction
2.2 Broadband Wireless Access Technologies
2.3 Wireless Local Area Networks Technologies
2.4 Personal Area Networks Technologies
2.5 Mobility Support in Heterogeneous Scenarios
2.6 Conclusions
3 Application Scenarios
3.1 Introduction
3.2 Military Applications
3.3 Network Connectivity
3.4 Wireless Sensor Networks
3.5 Search and Rescue
3.6 Vehicular Networks
3.7 Personal Content Dissemination
3.8 Conclusions
4 Security in Wireless Ad Hoc Networks
4.1 Introduction
4.2 Wireless Sensor Networks
4.3 Unattended WSN
4.4 Wireless Mesh Networks
4.5 Delay-Tolerant Networks
4.6 Vehicular Ad Hoc Networks (VANETs)
4.7 Conclusions and Open Research Issues
5 Architectural Solutions for End-User Mobility
5.1 Introduction
5.2 Mesh Networks
5.3 Wireless Sensor Networks
5.4 Conclusion
6 Experimental Work Versus Simulation in the Study of Mobile Ad Hoc Networks
6.1 Introduction
6.2 Overview of Mobile Ad Hoc Network Simulation Tools and Experimental Platforms
6.3 Gap Between Simulations and Experiments: Issues and Factors
6.4 Good Simulations: Validation, Verification and Calibration
6.5 Simulators and Testbeds: Future Prospects
6.6 Conclusion
Part II Mesh Networking
7 Resource Optimization in Multi radio Multichannel Wireless Mesh Networks
7.1 Introduction
7.2 Network and Interference Models
7.3 Maximum Link Activation Under the SINR Model
7.4 Optimal Link Scheduling
7.5 Joint Routing and Scheduling
7.6 Dealing with Channel Assignment and Directional Antennas
7.7 Cooperative Networking
7.8 Concluding Remarks and Future Issues
8 Quality of Service in Mesh Networks
8.1 Introduction
8.2 QoS Definition
8.3 A Taxonomy of Existing QoS Routing Approaches
8.4 Routing Protocols with Optimization-Based Path Selection
8.5 Routing Metrics for Minimum-Weight Path Selection
8.6 Feedback-Based Path Selection
8.7 Conclusions
Part III Opportunistic Networking
9 Applications in Delay-Tolerant and Opportunistic Networks
9.1 Application Scenarios
9.2 Challenges for Applications Over DTN
9.3 Critical Mechanisms for DTN Applications
9.4 DTN Applications (Case Studies)
9.5 Conclusion: Rethinking Applications for DTNs
10 Mobility Models in Opportunistic Networks
10.1 Introduction
10.2 Contact-Based Measurement, Analysis and Modeling
10.3 Trajectory Models
10.4 Implications for Network Protocol Design
10.5 New Paradigm: Delay-Resource Tradeoffs
11 Opportunistic Routing
11.1 Introduction
11.2 Cornerstones of Opportunistic Networks
11.3 Dealing with Uncertainty: Redundancy-Based Routing
11.4 Capitalizing on Structure: Utility-Based Forwarding
11.5 Hybrid Solutions: Combining Redundancy and Utility
11.6 Conclusion
12 Data Dissemination in Opportunistic Networks
12.1 Introduction
12.2 Initial Ideas: PodNet
12.3 Social-Aware Schemes
12.4 Publish/Subscribe Schemes
12.5 Global Optimization
12.6 Infrastructure-Based Approaches
12.7 Approaches Inspired by Unstructured p2p Systems
12.8 Further Readings
13 Task Farming in Crowd Computing
13.1 Introduction
13.2 Ideal Parallelism Model
13.3 Task Farming
13.4 Socially Aware Task Farming
13.5 Related Work
13.6 Conclusions and Future Work
Part IV Vanet
14 A Taxonomy of Data Communication Protocols for Vehicular Ad Hoc Networks
14.1 Introduction
14.2 Taxonomy of VANET Communication Protocols
14.3 Reliability-Oriented Geocasting Protocols
14.4 Time-Critical Geocasting Protocols
14.5 Small-Scale Routing Protocols
14.6 Large-Scale Routing
14.7 Summary
14.8 Conclusion and Future Work
15 Mobility Models, Topology and Simulations in VANET
15.1 Introduction and Motivation
15.2 Mobility Models
15.3 Mobility Simulators
15.4 Integrated Simulators
15.5 Modeling Vehicular Communications
15.6 Analysis of Connectivity in Highways
15.7 Conclusion and Future Work
16 Experimental Work on VANET
16.1 Introduction
16.2 MIT CarTel
16.3 UMass Diesel Net
16.4 SJTU Shanghai Grid
16.5 NCTU VANET Testbed
16.6 UCLA CVeT
16.7 GM DSRC Fleet
16.8 Fleet Net Project
16.9 Network on Wheels (NOW) Project
16.10 Advanced Safety Vehicles (ASVs)
16.11 Japan Automobile Research Institute (JARI)
17 MAC Protocols for VANET
17.1 Introduction
17.2 MAC Metrics
17.3 IEEE Standards for MAC Protocols for VANETs
17.4 Alternate MAC Protocols for VANET
17.5 Conclusion
18 Cognitive Radio Vehicular Ad Hoc Networks: Design, Implementation and Future Challenges
18.1 Introduction
18.2 Characteristics of Cognitive Radio Vehicular Networks
18.3 Applications of Cognitive Radio Vehicular Networks
18.4 CRV Network Architecture
18.5 Classification and Description of Existing Works on CRV Networks
18.6 Research Issues in CRVs
18.7 Conclusion
19 The Next Paradigm Shift: From Vehicular Networks to Vehicular Clouds
19.1 By Way of Motivation
19.2 The Vehicular Model
19.3 Vehicular Networks
19.4 Cloud Computing
19.5 Vehicular Clouds
19.6 How are Vehicular Clouds Different?
19.7 Feasible Instances of Vehicular Clouds
19.8 More Application Scenarios
19.9 Security and Privacy in Vehicular Clouds
19.10 Key Management
19.11 Research Challenges
19.12 Architectures for Vehicular Clouds
19.13 Resource Aggregation in Vehicular Clouds
19.14 A Simulation Study of VC
19.15 Future Work
19.16 Where to From Here?
Part V Sensor Networking
20 Wireless Sensor Networks with Energy Harvesting
20.1 Introduction
20.2 Node Platforms
20.3 Techniques of Energy Harvesting
20.4 Prediction Models
20.5 Protocols for EHWSNs
21 Robot-Assisted Wireless Sensor Networks: Recent Applications and Future Challenges
21.1 Introduction
21.2 Robot-Assisted Sensor Placement
21.3 Robot-Assisted Sensor Relocation
21.4 Robot-Assisted Sensor Maintenance
21.5 Future Challenges
22 Underwater Networks with Limited Mobility: Algorithms, Systems and Experiments
22.1 Introduction
22.2 Related Work
22.3 Decentralized Control Algorithm
22.4 General System Architecture and Design
22.5 Application-Specific Architecture and Design
22.6 Experiments and Results
22.7 Conclusions
23 Advances in Underwater Acoustic Networking
23.1 Introduction
23.2 Communication Architecture
23.3 Basics of Underwater Communications
23.4 Physical Layer
23.5 Medium Access Control Layer
23.6 Network Layer
23.7 Cross-Layer Design
23.8 Experimental Platforms
23.9 UW-Buffalo: An Underwater Acoustic Testbed at the University at Buffalo
23.10 Conclusions
9788126557219
Mobile AD HOC Networking : Cutting edge Directions - 2nd - New Delhi Wiley India 2013 - 864p.
Part I General Issues
1 Multihop Ad Hoc Networking: The Evolutionary Path
1.1 Introduction
1.2 MANET Research: Major Achievements and Lessons Learned
1.3 Multihop Ad Hoc Networks: From Theory to Reality
1.4 Summary and Conclusions
2 Enabling Technologies and Standards for Mobile Multihop Wireless Networking
2.1 Introduction
2.2 Broadband Wireless Access Technologies
2.3 Wireless Local Area Networks Technologies
2.4 Personal Area Networks Technologies
2.5 Mobility Support in Heterogeneous Scenarios
2.6 Conclusions
3 Application Scenarios
3.1 Introduction
3.2 Military Applications
3.3 Network Connectivity
3.4 Wireless Sensor Networks
3.5 Search and Rescue
3.6 Vehicular Networks
3.7 Personal Content Dissemination
3.8 Conclusions
4 Security in Wireless Ad Hoc Networks
4.1 Introduction
4.2 Wireless Sensor Networks
4.3 Unattended WSN
4.4 Wireless Mesh Networks
4.5 Delay-Tolerant Networks
4.6 Vehicular Ad Hoc Networks (VANETs)
4.7 Conclusions and Open Research Issues
5 Architectural Solutions for End-User Mobility
5.1 Introduction
5.2 Mesh Networks
5.3 Wireless Sensor Networks
5.4 Conclusion
6 Experimental Work Versus Simulation in the Study of Mobile Ad Hoc Networks
6.1 Introduction
6.2 Overview of Mobile Ad Hoc Network Simulation Tools and Experimental Platforms
6.3 Gap Between Simulations and Experiments: Issues and Factors
6.4 Good Simulations: Validation, Verification and Calibration
6.5 Simulators and Testbeds: Future Prospects
6.6 Conclusion
Part II Mesh Networking
7 Resource Optimization in Multi radio Multichannel Wireless Mesh Networks
7.1 Introduction
7.2 Network and Interference Models
7.3 Maximum Link Activation Under the SINR Model
7.4 Optimal Link Scheduling
7.5 Joint Routing and Scheduling
7.6 Dealing with Channel Assignment and Directional Antennas
7.7 Cooperative Networking
7.8 Concluding Remarks and Future Issues
8 Quality of Service in Mesh Networks
8.1 Introduction
8.2 QoS Definition
8.3 A Taxonomy of Existing QoS Routing Approaches
8.4 Routing Protocols with Optimization-Based Path Selection
8.5 Routing Metrics for Minimum-Weight Path Selection
8.6 Feedback-Based Path Selection
8.7 Conclusions
Part III Opportunistic Networking
9 Applications in Delay-Tolerant and Opportunistic Networks
9.1 Application Scenarios
9.2 Challenges for Applications Over DTN
9.3 Critical Mechanisms for DTN Applications
9.4 DTN Applications (Case Studies)
9.5 Conclusion: Rethinking Applications for DTNs
10 Mobility Models in Opportunistic Networks
10.1 Introduction
10.2 Contact-Based Measurement, Analysis and Modeling
10.3 Trajectory Models
10.4 Implications for Network Protocol Design
10.5 New Paradigm: Delay-Resource Tradeoffs
11 Opportunistic Routing
11.1 Introduction
11.2 Cornerstones of Opportunistic Networks
11.3 Dealing with Uncertainty: Redundancy-Based Routing
11.4 Capitalizing on Structure: Utility-Based Forwarding
11.5 Hybrid Solutions: Combining Redundancy and Utility
11.6 Conclusion
12 Data Dissemination in Opportunistic Networks
12.1 Introduction
12.2 Initial Ideas: PodNet
12.3 Social-Aware Schemes
12.4 Publish/Subscribe Schemes
12.5 Global Optimization
12.6 Infrastructure-Based Approaches
12.7 Approaches Inspired by Unstructured p2p Systems
12.8 Further Readings
13 Task Farming in Crowd Computing
13.1 Introduction
13.2 Ideal Parallelism Model
13.3 Task Farming
13.4 Socially Aware Task Farming
13.5 Related Work
13.6 Conclusions and Future Work
Part IV Vanet
14 A Taxonomy of Data Communication Protocols for Vehicular Ad Hoc Networks
14.1 Introduction
14.2 Taxonomy of VANET Communication Protocols
14.3 Reliability-Oriented Geocasting Protocols
14.4 Time-Critical Geocasting Protocols
14.5 Small-Scale Routing Protocols
14.6 Large-Scale Routing
14.7 Summary
14.8 Conclusion and Future Work
15 Mobility Models, Topology and Simulations in VANET
15.1 Introduction and Motivation
15.2 Mobility Models
15.3 Mobility Simulators
15.4 Integrated Simulators
15.5 Modeling Vehicular Communications
15.6 Analysis of Connectivity in Highways
15.7 Conclusion and Future Work
16 Experimental Work on VANET
16.1 Introduction
16.2 MIT CarTel
16.3 UMass Diesel Net
16.4 SJTU Shanghai Grid
16.5 NCTU VANET Testbed
16.6 UCLA CVeT
16.7 GM DSRC Fleet
16.8 Fleet Net Project
16.9 Network on Wheels (NOW) Project
16.10 Advanced Safety Vehicles (ASVs)
16.11 Japan Automobile Research Institute (JARI)
17 MAC Protocols for VANET
17.1 Introduction
17.2 MAC Metrics
17.3 IEEE Standards for MAC Protocols for VANETs
17.4 Alternate MAC Protocols for VANET
17.5 Conclusion
18 Cognitive Radio Vehicular Ad Hoc Networks: Design, Implementation and Future Challenges
18.1 Introduction
18.2 Characteristics of Cognitive Radio Vehicular Networks
18.3 Applications of Cognitive Radio Vehicular Networks
18.4 CRV Network Architecture
18.5 Classification and Description of Existing Works on CRV Networks
18.6 Research Issues in CRVs
18.7 Conclusion
19 The Next Paradigm Shift: From Vehicular Networks to Vehicular Clouds
19.1 By Way of Motivation
19.2 The Vehicular Model
19.3 Vehicular Networks
19.4 Cloud Computing
19.5 Vehicular Clouds
19.6 How are Vehicular Clouds Different?
19.7 Feasible Instances of Vehicular Clouds
19.8 More Application Scenarios
19.9 Security and Privacy in Vehicular Clouds
19.10 Key Management
19.11 Research Challenges
19.12 Architectures for Vehicular Clouds
19.13 Resource Aggregation in Vehicular Clouds
19.14 A Simulation Study of VC
19.15 Future Work
19.16 Where to From Here?
Part V Sensor Networking
20 Wireless Sensor Networks with Energy Harvesting
20.1 Introduction
20.2 Node Platforms
20.3 Techniques of Energy Harvesting
20.4 Prediction Models
20.5 Protocols for EHWSNs
21 Robot-Assisted Wireless Sensor Networks: Recent Applications and Future Challenges
21.1 Introduction
21.2 Robot-Assisted Sensor Placement
21.3 Robot-Assisted Sensor Relocation
21.4 Robot-Assisted Sensor Maintenance
21.5 Future Challenges
22 Underwater Networks with Limited Mobility: Algorithms, Systems and Experiments
22.1 Introduction
22.2 Related Work
22.3 Decentralized Control Algorithm
22.4 General System Architecture and Design
22.5 Application-Specific Architecture and Design
22.6 Experiments and Results
22.7 Conclusions
23 Advances in Underwater Acoustic Networking
23.1 Introduction
23.2 Communication Architecture
23.3 Basics of Underwater Communications
23.4 Physical Layer
23.5 Medium Access Control Layer
23.6 Network Layer
23.7 Cross-Layer Design
23.8 Experimental Platforms
23.9 UW-Buffalo: An Underwater Acoustic Testbed at the University at Buffalo
23.10 Conclusions
9788126557219