WiFi, WiMAX and LTE Multi-Hop Mesh Networks : Basic Communication Protocols and Application Areas.

By: Wei, Hung-YuContributor(s): Rykowski, Jaroqniew | Dixit, Sudhir | Rykowski, Jarogniew | Wei, Hung-YuMaterial type: TextTextSeries: Information and Communication Technology Series, SerPublisher: Hoboken : John Wiley & Sons, Incorporated, 2013Copyright date: ©2013Edition: 1st edDescription: 1 online resource (282 pages)Content type: text Media type: computer Carrier type: online resourceISBN: 9781118571118Subject(s): Ad hoc networks (Computer networks)Genre/Form: Electronic books.Additional physical formats: Print version:: WiFi, WiMAX and LTE Multi-Hop Mesh Networks : Basic Communication Protocols and Application AreasDDC classification: 621.384 LOC classification: TK5105.77.W45 2013Online resources: Click to View
Contents:
Cover -- Wiley Series on Information and Communication Technology -- Title page -- Copyright page -- Contents -- Foreword -- Preface -- About the Authors -- List of Figures -- List of Tables -- 1: Introduction -- 2: Architectural Requirements for Multi-hop and Ad-Hoc Networking -- 2.1. When and Where Do We Need Ad-Hoc Networking? -- 2.2. When Do We Need Multi-hop? How Many Hops Are Sufficient/Necessary? -- 2.3. Anonymity versus Authorization and Authentication -- 2.4. Security and Privacy in Ad-Hoc Networks -- 2.5. Security and Privacy in Multi-hop Networks -- 2.6. Filtering the Traffic in Ad-Hoc Networking and Multi-hop Relaying -- 2.7. QoS -- 2.8. Addressability -- 2.9. Searchability -- 2.10. Ad-Hoc Contexts for Next-Generation Searching -- 2.11. Personalization Aspects in Ad-Hoc Information Access -- 2.12. Multi-hop Networking: Technical Aspects -- 2.13. Summary -- 2.13.1. Do We Really Need Ad-Hoc and Multi-hop Networking? If So, When and Where? -- 2.13.2. When and Where Do We Need Ad-Hoc Networking? -- 2.13.3. How Do We Effectively Combine Anonymity/Privacy with Safety/Security? -- 2.13.4. How Do We Personalize Network Access, Including User-Oriented Information Filtering? -- 2.13.5. How Do We Access Places/Devices/Information in a Highly Dynamic Environment of an Ad-Hoc and Multi-hop Network Affecting Addressability, Searchability, and Accessibility of Data? -- 2.13.6. How Do We Support Frequently Dis- and Reconnected Users, Including Efficient Propagation of Important Information to Newcomers? -- 2.13.7. How Many Hops Are Allowed/Effective for a Typical Multi-hop Information Exchange? Is Relaying Affected with the Security/Privacy Issues? -- 3: Application Areas for Multi-hop and Ad-Hoc Networking -- 3.1. Telematics -- 3.1.1. Introduction to Telematics Applications -- 3.1.2. Ad-Hoc Enhanced Navigation Support.
3.1.3. Traffic Lights Assistance -- 3.1.4. CB-Net Application -- 3.1.5. City-Transportation Integrated Support -- 3.2. e-Ticket Applications -- 3.3. Telemedicine -- 3.4. Environment Protection -- 3.5. Public Safety -- 3.5.1. Ad-Hoc Monitoring for Public Safety Applications -- 3.5.2. Broadcasting Public Safety Information -- 3.6. Groupware -- 3.7. Personal, Targeted, Contextual Marketing and Shopping Guidance -- 3.8. Intelligent Building -- 3.8.1. "Intelligent Hospital" Idea -- 3.8.2. "Interactive Museum" Idea -- 3.8.3. Intelligent Ad-Hoc Cooperation at a Workplace -- 3.9. Business Aspects of Multi-hop and Ad-Hoc Networking -- 3.9.1. Monetary Unit for Ad-Hoc and Multi-hop Services -- 3.9.2. Which Ad-Hoc and Multi-hop Functionality Should Be Paid For? -- 3.9.3. Quality-of-Service and Trustability -- 3.9.4. Pay-per-Access Mode and Subscriptions -- 3.9.5. Legal Regulations -- 3.9.6. Ad-Hoc and Multi-hop Networking versus Commercial Networks and Network Providers -- 3.10. Summary -- 4: Mesh Networking Using IEEE 802.11 Wireless Technologies -- 4.1. IEEE 802.11 -- 4.1.1. WiFi and IEEE 802.11 Wireless LAN -- 4.1.2. IEEE 802.11 Mesh Network Architectures -- 4.2. IEEE 802.11s: Standard for WLAN Mesh Networking -- 4.2.1. Additional Functions in 802.11s -- 4.2.2. WiFi Certification and Deployments of IEEE 802.11s -- 4.3. Summary -- 5: Wireless Relay Networking Using IEEE 802.16 WiMAX Technologies -- 5.1. IEEE 802.16 Overview and Architecture -- 5.2. IEEE 802.16j Relay System Overview -- 5.2.1. Nontransparent Relay versus Transparent Relay -- 5.2.2. Connection Types -- 5.2.3. MAC PDU Transmission Mode -- 5.2.4. Relay MAC PDU -- 5.2.5. Subheaders in Relay MAC PDU -- 5.3. IEEE 802.16j Frame Structure -- 5.3.1. Frame Structure in Nontransparent Mode -- 5.3.2. Frame Structure in Transparent Mode -- 5.4. Path Management in 802.16j Relay.
5.4.1. Explicit Path Management -- 5.4.2. Implicit Path Management -- 5.4.3. Contiguous Integer Block CID Assignment for Implicit Path Management -- 5.4.4. Bit Partition CID Assignment for Implicit Path Management -- 5.4.5. Path Selection and Metrics -- 5.5. Radio Resource Management -- 5.5.1. RRM with Distributed Scheduling -- 5.5.2. Bandwidth Request Mechanism in WiMAX -- 5.5.3. Downlink Flow Control -- 5.5.4. RRM with Centralized Scheduling -- 5.5.5. SS-Initiated Bandwidth Request in Centralized Scheduling -- 5.6. Interference Management -- 5.6.1. Interference Measurement -- 5.6.2. RS Neighborhood Discovery and Measurements -- 5.6.3. Relay Amble (R-Amble) Transmission -- 5.7. Initialization and Network Entry -- 5.7.1. Network Entry Overview -- 5.7.2. Network Entry for Relay Station -- 5.7.3. Fast Reentry -- 5.7.4. Network Entry for Subscriber Station (Through RS) -- 5.8. Mobility Management and Handoff -- 5.8.1. Design Issues: Mobility Management in Multi-hop Relay Network -- 5.8.2. Overview of Mobile Station Handoff Protocol Design in 802.16j -- 5.8.3. Neighborhood Network Topology Advertisement -- 5.8.4. Mobile Node Scanning -- 5.8.5. Association -- 5.8.6. Handoff Execution -- 5.8.7. Handoff Optimization with Context Transfer -- 5.8.8. Mobile Relay Station Handoff -- 5.9. Power Management -- 5.9.1. Sleep Mode -- 5.9.2. Idle Mode -- 5.10. HARQ and Reliable Transmission -- 5.10.1. Design Issues: HARQ in Multi-hop Relay Network -- 5.10.2. Overview of HARQ Design in 802.16j -- 5.10.3. HARQ in Centralized Scheduling -- 5.10.4. Downlink HARQ in Nontransparent Mode -- 5.10.5. Downlink HARQ in Transparent Mode: Hop-by-Hop HARQ Operation -- 5.10.6. Downlink HARQ in Transparent Mode: RS-assisted HARQ -- 5.10.7. Uplink HARQ in Nontransparent Mode -- 5.10.8. Uplink HARQ in Transparent Mode -- 5.10.9. HARQ in Distributed Scheduling.
5.11. Multicast, Broadcast, and RS Grouping -- 5.11.1. Multicast and Broadcast -- 5.12. RS Grouping -- 5.13. Summary -- 6: Wireless Relay Networking with Long Term Evolution (LTE) -- 6.1. Overview of the LTE Relay System -- 6.1.1. LTE Relay Deployment Scenario -- 6.1.2. Overview of Resource Partitioning in In-Band Relay -- 6.2. Physical Layer for LTE Relay -- 6.2.1. Physical Layer Channels -- 6.2.2. Frame Structure in Physical Layer Channels -- 6.3. LTE Relay System Architecture -- 6.3.1. Protocol Stacks for Radio Interface -- 6.3.2. S1 Interface -- 6.3.3. RN Initialization and Startup Procedure -- 6.4. LTE Relay System Design Issues -- 6.4.1. Overview of Architecture and Design Issues -- 6.4.2. Design Issue: Downlink Flow Control -- 6.4.3. Design Issue: End-to-End QoS Configuration -- 6.4.4. Design Issue: Un Interface Configuration -- 6.4.5. Design Issue: Connection Establishment -- 6.4.6. Design Issue: Radio Link Failure and Connection Reestablishment -- 6.4.7. Design Issue: Other Design Options -- 6.5. Future Development in LTE Relay -- 6.5.1. Mobile Relay -- 6.5.2. Advanced Link Transmission -- 6.5.3. Other Deployment Scenarios and Architecture -- 6.6. Summary -- 7: Summary -- References -- Index.
Summary: Wifi, WiMAX, and Cellular Multihop Networks presents an overview of WiFi-based and WiMAX-based multihop relay networks. As the first text to cover IEEE 802.16j multihop hop relay technology, this revolutionary resource explores the latest advances in multi-hop and ad-hoc networking. Not only does this reference provide the technological aspects, but also the applications for the emerging technology and architectural issues. Ranging from introductory material to advanced topics, this guidebook is essential for engineers, researchers, and students interested in learning more about WiFi and WiMAX multihop relay networks.
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Cover -- Wiley Series on Information and Communication Technology -- Title page -- Copyright page -- Contents -- Foreword -- Preface -- About the Authors -- List of Figures -- List of Tables -- 1: Introduction -- 2: Architectural Requirements for Multi-hop and Ad-Hoc Networking -- 2.1. When and Where Do We Need Ad-Hoc Networking? -- 2.2. When Do We Need Multi-hop? How Many Hops Are Sufficient/Necessary? -- 2.3. Anonymity versus Authorization and Authentication -- 2.4. Security and Privacy in Ad-Hoc Networks -- 2.5. Security and Privacy in Multi-hop Networks -- 2.6. Filtering the Traffic in Ad-Hoc Networking and Multi-hop Relaying -- 2.7. QoS -- 2.8. Addressability -- 2.9. Searchability -- 2.10. Ad-Hoc Contexts for Next-Generation Searching -- 2.11. Personalization Aspects in Ad-Hoc Information Access -- 2.12. Multi-hop Networking: Technical Aspects -- 2.13. Summary -- 2.13.1. Do We Really Need Ad-Hoc and Multi-hop Networking? If So, When and Where? -- 2.13.2. When and Where Do We Need Ad-Hoc Networking? -- 2.13.3. How Do We Effectively Combine Anonymity/Privacy with Safety/Security? -- 2.13.4. How Do We Personalize Network Access, Including User-Oriented Information Filtering? -- 2.13.5. How Do We Access Places/Devices/Information in a Highly Dynamic Environment of an Ad-Hoc and Multi-hop Network Affecting Addressability, Searchability, and Accessibility of Data? -- 2.13.6. How Do We Support Frequently Dis- and Reconnected Users, Including Efficient Propagation of Important Information to Newcomers? -- 2.13.7. How Many Hops Are Allowed/Effective for a Typical Multi-hop Information Exchange? Is Relaying Affected with the Security/Privacy Issues? -- 3: Application Areas for Multi-hop and Ad-Hoc Networking -- 3.1. Telematics -- 3.1.1. Introduction to Telematics Applications -- 3.1.2. Ad-Hoc Enhanced Navigation Support.

3.1.3. Traffic Lights Assistance -- 3.1.4. CB-Net Application -- 3.1.5. City-Transportation Integrated Support -- 3.2. e-Ticket Applications -- 3.3. Telemedicine -- 3.4. Environment Protection -- 3.5. Public Safety -- 3.5.1. Ad-Hoc Monitoring for Public Safety Applications -- 3.5.2. Broadcasting Public Safety Information -- 3.6. Groupware -- 3.7. Personal, Targeted, Contextual Marketing and Shopping Guidance -- 3.8. Intelligent Building -- 3.8.1. "Intelligent Hospital" Idea -- 3.8.2. "Interactive Museum" Idea -- 3.8.3. Intelligent Ad-Hoc Cooperation at a Workplace -- 3.9. Business Aspects of Multi-hop and Ad-Hoc Networking -- 3.9.1. Monetary Unit for Ad-Hoc and Multi-hop Services -- 3.9.2. Which Ad-Hoc and Multi-hop Functionality Should Be Paid For? -- 3.9.3. Quality-of-Service and Trustability -- 3.9.4. Pay-per-Access Mode and Subscriptions -- 3.9.5. Legal Regulations -- 3.9.6. Ad-Hoc and Multi-hop Networking versus Commercial Networks and Network Providers -- 3.10. Summary -- 4: Mesh Networking Using IEEE 802.11 Wireless Technologies -- 4.1. IEEE 802.11 -- 4.1.1. WiFi and IEEE 802.11 Wireless LAN -- 4.1.2. IEEE 802.11 Mesh Network Architectures -- 4.2. IEEE 802.11s: Standard for WLAN Mesh Networking -- 4.2.1. Additional Functions in 802.11s -- 4.2.2. WiFi Certification and Deployments of IEEE 802.11s -- 4.3. Summary -- 5: Wireless Relay Networking Using IEEE 802.16 WiMAX Technologies -- 5.1. IEEE 802.16 Overview and Architecture -- 5.2. IEEE 802.16j Relay System Overview -- 5.2.1. Nontransparent Relay versus Transparent Relay -- 5.2.2. Connection Types -- 5.2.3. MAC PDU Transmission Mode -- 5.2.4. Relay MAC PDU -- 5.2.5. Subheaders in Relay MAC PDU -- 5.3. IEEE 802.16j Frame Structure -- 5.3.1. Frame Structure in Nontransparent Mode -- 5.3.2. Frame Structure in Transparent Mode -- 5.4. Path Management in 802.16j Relay.

5.4.1. Explicit Path Management -- 5.4.2. Implicit Path Management -- 5.4.3. Contiguous Integer Block CID Assignment for Implicit Path Management -- 5.4.4. Bit Partition CID Assignment for Implicit Path Management -- 5.4.5. Path Selection and Metrics -- 5.5. Radio Resource Management -- 5.5.1. RRM with Distributed Scheduling -- 5.5.2. Bandwidth Request Mechanism in WiMAX -- 5.5.3. Downlink Flow Control -- 5.5.4. RRM with Centralized Scheduling -- 5.5.5. SS-Initiated Bandwidth Request in Centralized Scheduling -- 5.6. Interference Management -- 5.6.1. Interference Measurement -- 5.6.2. RS Neighborhood Discovery and Measurements -- 5.6.3. Relay Amble (R-Amble) Transmission -- 5.7. Initialization and Network Entry -- 5.7.1. Network Entry Overview -- 5.7.2. Network Entry for Relay Station -- 5.7.3. Fast Reentry -- 5.7.4. Network Entry for Subscriber Station (Through RS) -- 5.8. Mobility Management and Handoff -- 5.8.1. Design Issues: Mobility Management in Multi-hop Relay Network -- 5.8.2. Overview of Mobile Station Handoff Protocol Design in 802.16j -- 5.8.3. Neighborhood Network Topology Advertisement -- 5.8.4. Mobile Node Scanning -- 5.8.5. Association -- 5.8.6. Handoff Execution -- 5.8.7. Handoff Optimization with Context Transfer -- 5.8.8. Mobile Relay Station Handoff -- 5.9. Power Management -- 5.9.1. Sleep Mode -- 5.9.2. Idle Mode -- 5.10. HARQ and Reliable Transmission -- 5.10.1. Design Issues: HARQ in Multi-hop Relay Network -- 5.10.2. Overview of HARQ Design in 802.16j -- 5.10.3. HARQ in Centralized Scheduling -- 5.10.4. Downlink HARQ in Nontransparent Mode -- 5.10.5. Downlink HARQ in Transparent Mode: Hop-by-Hop HARQ Operation -- 5.10.6. Downlink HARQ in Transparent Mode: RS-assisted HARQ -- 5.10.7. Uplink HARQ in Nontransparent Mode -- 5.10.8. Uplink HARQ in Transparent Mode -- 5.10.9. HARQ in Distributed Scheduling.

5.11. Multicast, Broadcast, and RS Grouping -- 5.11.1. Multicast and Broadcast -- 5.12. RS Grouping -- 5.13. Summary -- 6: Wireless Relay Networking with Long Term Evolution (LTE) -- 6.1. Overview of the LTE Relay System -- 6.1.1. LTE Relay Deployment Scenario -- 6.1.2. Overview of Resource Partitioning in In-Band Relay -- 6.2. Physical Layer for LTE Relay -- 6.2.1. Physical Layer Channels -- 6.2.2. Frame Structure in Physical Layer Channels -- 6.3. LTE Relay System Architecture -- 6.3.1. Protocol Stacks for Radio Interface -- 6.3.2. S1 Interface -- 6.3.3. RN Initialization and Startup Procedure -- 6.4. LTE Relay System Design Issues -- 6.4.1. Overview of Architecture and Design Issues -- 6.4.2. Design Issue: Downlink Flow Control -- 6.4.3. Design Issue: End-to-End QoS Configuration -- 6.4.4. Design Issue: Un Interface Configuration -- 6.4.5. Design Issue: Connection Establishment -- 6.4.6. Design Issue: Radio Link Failure and Connection Reestablishment -- 6.4.7. Design Issue: Other Design Options -- 6.5. Future Development in LTE Relay -- 6.5.1. Mobile Relay -- 6.5.2. Advanced Link Transmission -- 6.5.3. Other Deployment Scenarios and Architecture -- 6.6. Summary -- 7: Summary -- References -- Index.

Wifi, WiMAX, and Cellular Multihop Networks presents an overview of WiFi-based and WiMAX-based multihop relay networks. As the first text to cover IEEE 802.16j multihop hop relay technology, this revolutionary resource explores the latest advances in multi-hop and ad-hoc networking. Not only does this reference provide the technological aspects, but also the applications for the emerging technology and architectural issues. Ranging from introductory material to advanced topics, this guidebook is essential for engineers, researchers, and students interested in learning more about WiFi and WiMAX multihop relay networks.

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Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2018. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries.

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