1. Challenges in Low Power Communication Protocol Design & Implementation��A SensiumTM Case Study Okundu C. Omeni, Alan CW Wong, Declan McDonagh, Alison Burdett
Toumaz Technology Ltd, UK
www.toumaz.com
okundu.omeni@toumaz.com
2. 2 Talk Outline Application area
Available standard-based solutions & motivation for a proprietary solution
Toumaz’s Sensium communication protocol (NSP)
Implementation & Performance details
Summary
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4. 4 Medical Body Area Network Application Requirements Low power
Low cost
For some applications (digital patch), devices would be disposable
Robustness
Reliability
Security
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6. 6 Sensium Nano Sensor Protocol (NSP) primary network topology Star topology
Central node is called a Basestation & terminal (power constrained) nodes targets
Target nodes can roam between Basestations
Basestations can communicate
7. 7 Main NSP Features & Terminologies Star topology (Basestation - Target) network Architecture
Network of Basestation and Targets termed a cluster
FDMA/TDMA channel access
Poll based access mechanism
LBT if required by regulation
Acknowledged protocol
Dynamic Time Slotting
Wakeup Fallback Time (WFT) increases autonomy
Cross-Layer optimization
8. 8 Additional NSP Features Word level hamming error CODEC (15,11)
Inverse parity bit also included (guarantees bit transitions irrespective of data)
Frame level error detection using CRC16
MAC Word masking provides data whitening
Communication post-link establishment is based on address recognition
Support for time-slot enforcement
Security mechanisms based on AES-128
Timing Synchronization between Targets & Basestation
9. 9 Sensium NSP Communication modes In the next few slides I will go through the various communication modes that are supported by the NSP
I would also be highlighting applications which could use these modes
10. 10 Protocol Handshake Process 1�BASESTATION to TARGET (DEFAULT) Communication
11. 11 Protocol Handshake Process 2�TARGET TO BASESTATION COMMUNICATIONS
12. 12 Protocol Handshake Process 3�BASESTATION TO BASESTATION COMMUNICATIONS
13. 13 Protocol Handshake Process 4�TARGET BROADCAST COMMUNICATION
14. 14 Protocol Handshake Process 5�BASESTATION BROADCAST COMMUNICATION
15. 15 Message Frame Formats
16. 16 Link Establishment Basestation finds vacant RF Channel from a list using RSSI & LBT (depending on regulatory requirements)
Transmits BSEEK message and listens for Target response. Repeats this cycle until a response is received or it times out.
Target finds active channel and listens for BSEEK. If not found in time window, it moves to the next active channel. If found, it responds, receives an address and a link is established
17. 17 SLEEP/WAKEUP CYCLES After Link establishment, a Target goes through SLEEP/WAKEUP cycles.
During SLEEP, sensor data may be acquired (while rest of system is powered-down)
On WAKEUP, this data can be transmitted to the Basestation
The Basestation is usually always active, as it services multiple Targets and also listens for possible ALARMS
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20. 20 Relative Performance
21. 21 The Sensium Ecosystem
22. 22 IEEE 802.15.6 – BAN Standard group Formed in 2006 to develop a power efficient wireless network protocol for on-body applications
Medical/Healthcare applications are the main target for this standard
Toumaz is part of a consortium MedWiN formed with 3 other companies – TI, GE & Philips Research to propose a solution for this standard which meets the low power and other requirements of the medical applications outlined earlier
The standard development process is currently at the baseline selection process and hopefully this phase would be completed by the end of the year
We are cautiously hopeful that the final standard that comes out of this process would be at least as power efficient as Toumaz’s solution
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