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Project: IEEE P802.15 Working Group for Wireless Personal Area Networks (WPANs)

Project: IEEE P802.15 Working Group for Wireless Personal Area Networks (WPANs) Submission Title: [Some MAC Requirements for Neighborhood Area Networks] Date Submitted: [13 May, 2008] Source: [Benjamin A. Rolfe] Company [Blind Creek Associates]

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Project: IEEE P802.15 Working Group for Wireless Personal Area Networks (WPANs)

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  1. Project: IEEE P802.15 Working Group for Wireless Personal Area Networks (WPANs) Submission Title: [Some MAC Requirements for Neighborhood Area Networks] Date Submitted: [13 May, 2008] Source: [Benjamin A. Rolfe] Company [Blind Creek Associates] [George Flammer] Company [Silver Spring Networks] Address [] Voice:[+1.408.395.7207] E-Mail:[ben@blindcreek.com, gflammer@silverspringnet.com] Re: [] Abstract: Discussion of some critical MAC requirements derived from NAN characteristics and relates them to 802.15.4 MAC Purpose: Contribution to technical requirements definition and discussion for task group 15.4e Notice: This document has been prepared to assist the IEEE P802.15. It is offered as a basis for discussion and is not binding on the contributing individual(s) or organization(s). The material in this document is subject to change in form and content after further study. The contributor(s) reserve(s) the right to add, amend or withdraw material contained herein. Release: The contributor acknowledges and accepts that this contribution becomes the property of IEEE and may be made publicly available by P802.15. Rolfe

  2. MAC Requirements Considerations Neighborhood Area Networks and Utility Networks Benjamin A. Rolfe ben@blindcreek.com Rolfe

  3. Outline • What is NAN? • NAN Application Example • Critical MAC Characteristics • NAN related to 4e MAC efforts Rolfe

  4. What does NAN Mean to Me? • Connect transparently out the door, down the street… • Connecting devices IN the home, and then… • Connecting devices ON the home • Long reach with short range (multi-hop) • Know your Neighbor • Ad-hoc associations and forwarding • Large scale networks • Dynamic scalability • Rugged individualism • Not dependent upon infrastructure • Forms it’s own connections and paths • Adaptive • Heterogeneous • May include infrastructure bridging points • Private • Multiple private networks simultaneously • Cooperation between private networks Rolfe

  5. What does NAN Mean to Me? • Connect transparently out the door, down the street… • Devices ON the home • Devices IN the home • Long reach with short range (multi-hop) • Large scale networks • Dynamic scalability • Rugged individualism • Not dependent upon infrastructure • Forms it’s own connections and paths • Adaptive • Heterogeneous • May include infrastructure bridging points • Private • Multiple private networks simultaneously • Cooperation between private networks Rolfe

  6. What does NAN Mean to Me? Looks a lot like a MESH Rolfe

  7. NAN Architecture Rolfe

  8. Example: Utility Network • Utility Networks • Integrated Monitoring and Control • Wide area distributed • Low data rate / Low duty cycle • Ubiquitous Rolfe

  9. Utility Networks Architecture Reference: 15-08-0199-00-wng0 Rolfe

  10. Utility Networks Overview Utility Automation • Need for Standard-based approach • Cost, availability, risk, efficiency • Interoperability between vendors needed • Low technical risk tolerance • Keep It Simple and Super Reliable (KISSR) • Distributed and Diverse • Diverse physical environments • Dispersed geographically • Distributed Process Control • Moderate data rates • High reliability and secure • Simple Provisioning, long service life • Constrained costs Reference: 15-08-0199-00-wng0 Rolfe

  11. Key Needs • Low Data Rates • Low rate of data collection < 1MByte/day/device nominal • Predictable Latency (Hop to hop must be controlled) • Different kinds of event/response requirements • Highly reliable and secure • Robust links, positive error detection, route diversity • Perceived security, privacy assuranc. • Multiple “privacy domains” • Scalability • Simple, Consistent and Cost Effective Provisioning • Ubiquitous, connected “always on” • Constrained costs • Very large number of nodes • Total cost of ownership • Long service life (in-place upgradeable) Rolfe

  12. Key MAC Characteristics • Data Characteristics • MESH and Network Management • Low Overhead • Performance Characteristics • Flexibility • Cost Considerations Rolfe

  13. Data Characteristics • Upper Layers use IP • Effective handling of IP critical • Fragmentation in the MAC? • Critical data delivery • Strong error detection (longer CRC) • Link assessment tools • Adaptive techniques? • Privacy • Classes of Service • Prioritization (user and channel access) Rolfe

  14. MESH • MESH support • Very large potential network size • High spectral reuse efficiency • Multi-hops with large spans • Redundant paths w/ mesh parallelism • ‘Pre-healing’ vs. ‘self-healing’ • Self-balancing • Prioritization of traffic • Dynamic response to environment Rolfe

  15. Performance Characteristics • Deterministic performance • Latency controlled hop to hop • Hop span: 15-20 hops not unusual • Scalability • Peer-to-Peer, Self-forming and maintaining • Minimal complexity • Flexible • Path redundancy/diversity • Robustness • Environment and Co-existence • Link quality • Error detection and recovery limitations • Multi-level Security Rolfe

  16. Flexibility • PHY Support Extensibility • 15.4 PHY diversity • DSSS @ 900MHz and 2.4 • Multiple modulations • Multiple spreading mechanisms • UWB and CSS (15.4a) • Regional PHYs (15.4c, 15.4d) • Why stop there… • New NAN PHY? Rolfe

  17. MAC Efforts • QoS • Latency • Classes of service (prioritization) • Channel utilization (hopping/agility) • Distributed network management • Distributed (Peer-to-Peer, ad-hoc) Pico-Net • “belonging” to multiple logical PNs • Robustness • Stronger link quality assessment and reporting • Stronger Error detection (CRC) • Other options? • Privacy • Key distribution in-band? • Device level authentication • Flexible support • MAC layer Fragmentation/de-Fragmentation? • Network (and device) Management Rolfe

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