Maria Rita Palattella (backup: Alfredo Grieco) 10min

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Presentation transcript:

Maria Rita Palattella (backup: Alfredo Grieco) 10min What is IEEE802.15.4e TSCH? Maria Rita Palattella (backup: Alfredo Grieco) 10min

Raw Ideas Deterministic networking Adapted to a priori flows Time Sync Scalable with distributed TS allocation TSCH more controllable, Trade off between energy, robustness and latency Several isolated flows (Traffic Engineering) Predictable power consumption Compressed duty cycle Time sync’ed mesh protocols

IEEE802.15.4e TSCH MAC amendment to the existing IEEE 802.15.4-2006 std. Prime characteristics: Based on IEEE802.15.4-2006 PHY (to profit from embedded PHYs) TSCH: TimeSlotted (Synchronized), to allow for distributed implementation TSCH:Channel Hopping, to give resilience to interference/multi-path fading

IEEE802.15.4e TSCH history 2006: TSCH approach emerges in the proprietary Time Synchronized Mesh Protocol (TSMP) 2008: TSMP is standardized in ISA100.11a The IEEE 802.15.4e Working group is created. Issue: IEEE 802.15.4-2006 MAC is ill-suited for low-power multi-hop network because of (i) high energy consumption due to relay/router nodes (ii) use of a single channel that implies interference and multi-path fading Final aim: to redesign the existing IEEE 802.15.4-2006 MAC Std. and make it suitable for low-power multi-hop networks in industrial applications 2009: TSMP is standardized in WirelessHART 2010: Part of IEEE 802.15.4e draft 2011: IEEE802.15.4e draft in Sponsor Ballot (opened on 27 July 2011 and closed on 28 August with 96% of votes being affirmative) 16 April 2012: IEEE802.15.4e TSCH published

IEEE802.15.4e TimeSlotted CH TSCH: TimeSlotted (Synchronized) Time is divided in time slots All motes are synchronized to a given slotframe Slotframe: group of time slots which repeats over time Number of time slots per slotframe is tunable A single slot is long enough for the transmitter to send a maximum length packet and for the receiver to send back an ACK 1 2 … 1 2 … 99 99 slotframe t cycle k cycle (k + 1)

Deterministic Networking TDM + Synchronization + Time formatted in Slotframe(s) Adapted to deterministic traffic (known a priori) a single time slot is a unit of throughput that can allocated to a deterministic flow Adapted to several isolated flows (Traffic Engineering) Optimized path and track per single flow Network synchronization and Timely transmission no collision and virtually no jitter

IEEE802.15.4e TSCH Schedule 1/2 Each mote follows a communication schedule A schedule is a matrix of cells, each of them indexed by a slotOffset and a channelOffset Each cell can be assigned to a pair of motes, in a given direction A scheduled cell can be used by one and/or multiple couples of devices (i.e., dedicated and/or shared) Predictable (low) power consumption motes wake up only when needed, according to the schedule

IEEE802.15.4e TSCH Schedule 2/2 A schedule is built according to the specific requirements of the application Trade-off between between energy consumption, robustness and latency Different approaches for building a schedule: Centralized (e.g., PCE-based) - PCE responsible for building and maintaining the schedule - Efficient for static networks Distributed (e.g., MPLS-like) - Nodes decide locally which cells they will use for communicating with their neighbors - Suitable for mobile networks with many gateways - Scalable with large network size IEEE 802.15.4e defines how the MAC executes a schedule but it does not specify how such schedule is built!!! 8

IEEE 802.15.4e TS Channel Hopping 1/2 The channel offset is translated to a frequency f (i.e., a real channel) using a translation function ASN 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 15 1 channelOffset slotOffset 0 1 2 3 4 5 6 t Slotframe cycle k (k + 1) (k + 2) (k + 3) Channel ch15 ch22 ch13 ch20

IEEE 802.15.4e TS Channel Hopping 2/2 A given mote sends subsequent packets on different channels Interference and multipath fading are mitigated Reliability and Robustness 16 channels are available in the 2.4GHz frequency band (optional blacklist) A single time slot can be used by multiple pairs of nodes Network capacity is increased