1. doc.: IEEE 802.15-<doc#>
<month year>
doc.: IEEE <doc#>
July 2008
Project: IEEE P Working Group for Wireless Personal Area Networks (WPANs)
Submission Title: [WiseMAC – HA : A Flexible, Scalable, Robust and Ultra Low Power
MAC Protocol for Medical BANs]
Date Submitted: [10 July, 2008]
Source: [Jérôme Rousselot] Company [CSEM SA]
Address [Jaquet-Droz 1, CH-2002 Neuchatel, Switzerland]
Voice:[ ], FAX: [ ],
Re: [IEEE , Original document]
Abstract: WiseMAC-HA, a MAC protocol designed specifically for body area networks, is presented and evaluated. Its design guarantees robustness against interferences and node failures, flexibility in network topology, scalability in network size, coexistence with independent networks and an ultra low power consumption.
Purpose: [Scalable Medium Access Control protocol for Medical BAN.]
Notice: This document has been prepared to assist the IEEE P 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 P
Jérôme Rousselot, CSEM
<author>, <company>

2. doc.: IEEE 802.15-<doc#>
<month year>
doc.: IEEE <doc#>
July 2008
WiseMAC – HA
A Flexible, Scalable, Robust and Ultra Low Power MAC Protocol for Medical BANs
This presentation describes and evaluates
CSEM MAC Proposal
for Medical Body Area Networks
WiseMAC: ULP WSN
High Availability: More Robust + Better bandwidth usage
Jérôme Rousselot, CSEM
<author>, <company>

3. doc.: IEEE 802.15-<doc#>
<month year>
doc.: IEEE <doc#>
July 2008
Outline
Targeted BAN Applications and Requirements
Ultra Low Power MAC Protocols
The WiseMAC High Availability Protocol
Performance Evaluation
Conclusion
Description of the Applications we are targeting
Problems faced by ULP MAC protocols
Presentation of our Ultra Low Power Medium Access Control Protocol, efficient with many phy layers
Analytical performance evaluation: use case with FM-UWB
Conclusion
Jérôme Rousselot, CSEM
<author>, <company>

4. Targeted Applications
<month year>
doc.: IEEE <doc#>
July 2008
Targeted Applications
Medical Body Area Networks
Continuous measurements
Main Requirements
Low Power
Scalability
Robustness
Coexistence
Medical Body Area Networks
Increased temporal resolution of health parameters
Enhanced patient mobility, Better control of drug intake
Requirements
Ultra Low Power (µW)‏
Low Complexity
Portable (Mobility)
Robust and Reliable
Good Coexistence
Transition: There are several ways to organize communications to reduce power consumption
[ESENSE 2006]
Jérôme Rousselot, CSEM
<author>, <company>

5. Ultra Low Power MAC Design
<month year>
doc.: IEEE <doc#>
July 2008
Ultra Low Power MAC Design
Types of Energy Waste
Idle
Listening
Signaling
Overhead
Useless
Talking
MAC Protocol Families
Overhearing
Collisions
Radio in Rx Mode
Radio in Tx Mode
ULP MAC
Deliver messages reliably and efficiently
Means of Action: select radio states
Deterministic or Stochastic
Compare to IEEE Beacon:
Limited Low Power Mode, Single Point of Failure, No coexistence (signaling traffic collisions)
Conclusion: Asynchronous Protocols Scale Better !
Transition: How to communicate asynchronously ?
Jérôme Rousselot, CSEM
<author>, <company>

6. Ultra Low Power MAC Design
<month year>
doc.: IEEE <doc#>
July 2008
Ultra Low Power MAC Design
Types of Energy Waste
Idle
Listening
Signaling
Overhead
Useless
Talking
MAC Protocol Families
Overhearing
Collisions
Radio in Rx Mode
Radio in Tx Mode
No Synchronization
ULP MAC
Deliver messages reliably and efficiently
Means of Action: select radio states
Deterministic or Stochastic
Compare to IEEE Beacon:
Limited Low Power Mode, Single Point of Failure, No coexistence (signaling traffic collisions)
Conclusion: Asynchronous Protocols Scale Better !
Transition: How to communicate asynchronously ?
More Scalable
Jérôme Rousselot, CSEM
<author>, <company>

7. WiseMAC Ultra Low Power MAC Scheme
<month year>
doc.: IEEE <doc#>
July 2008
WiseMAC Ultra Low Power MAC Scheme
Periodic Sampling
Link-local Synchronization Only
WiseMAC
Periodic Sampling
Asynchronous Sleep
Conclusion: Opportunistic Local Synchronization
Inefficient Broadcasts
Optimizations exist (X-MAC,CSMA- MPS, SyncWUF) but do not bring significant advantages (in steady state)‏
Transition: How well does this scheme perform ? As efficiently as TDMA...
WiseNET: an ultralow-power wireless sensor network solution, IEEE Computer, Enz et. al., 2004.
WiseMAC: An Ultra Low Power MAC Protocol for Multi-hop Wireless Sensor Networks, El-Hoiydi, Decotignie, AlgoSens 2004.
Jérôme Rousselot, CSEM
<author>, <company>

8. WiseMAC Ultra Low Power MAC Scheme
<month year>
doc.: IEEE <doc#>
July 2008
WiseMAC Ultra Low Power MAC Scheme
Store
Forward
N = 10
Node
Node
Node
LMAC
Crankshaft
WiseMAC Deviations from Ideality
High Traffic: low cost of wake-up preamble
Low Traffic: only the cost of sampling
S-MAC
SCP-MAC
WiseMAC
Ideal
Store and Forward Scenario
Typical traffic scenario in sparse sensor networks
Ideal Protocol
L-MAC, Crankshaft: Idle Listening
S-MAC: Idle Listening + Overhearing
SCP-MAC: very optimistic, but still overhearing
WiseMAC as good as TDMA schemes
Conclusion: WiseMAC close to ideal on a broad range of traffic
Transition: What happens in case of interference ? They are an important problem for mobile networks
(Texas Instruments CC 2420 radio transceiver)
Low Power Medium Access Control Protocols for Wireless Sensor Networks, Jérôme Rousselot, Amre El-Hoiydi and Jean-Dominique Decotignie, European Wireless Conference 2008 (EW 2008), June 2008, Prague, Czech Republic.
Jérôme Rousselot, CSEM
<author>, <company>

9. doc.: IEEE 802.15-<doc#>
<month year>
doc.: IEEE <doc#>
July 2008
MultiChannel WiseMAC
Three Channels
What is a channel ?
MultiChannel WiseMAC allows autonomous and independent node reconfiguration
Detect-and-Avoid + Rediscovery
Added benefit: reduced overhearing
Conclusion: MultiChannel WiseMAC allows continuity of service at the cost of a temporary performance degradation (increase of latency and power consumption) ‏
Transition: Throughput limitation
Jérôme Rousselot, CSEM
<author>, <company>

10. doc.: IEEE 802.15-<doc#>
<month year>
doc.: IEEE <doc#>
July 2008
MultiChannel WiseMAC
Advantages
Ultra Low Power
Robustness to Interference
Scalability with network size
Flexibility (star and mesh topologies)
Low latency
Drawbacks
Inefficient Broadcasts
Limited Throughput
Sub-optimal for heterogeneous networks
Address WiseMAC limitations by complementing it with an interoperable high throughput protocol
TW -> 0 = CSMA
Conclusion: Autonomous Mode Change – No Signaling required
Transition: How well does it perform ?
Have some nodes switch to an interoperable mode that does not exhibit limited throughput = CSMA (IEEE Non Beacon Enabled Mode)‏
WiseMAC High Availability
Jérôme Rousselot, CSEM
<author>, <company>

11. doc.: IEEE 802.15-<doc#>
<month year>
doc.: IEEE <doc#>
July 2008
Power Consumption
Sensor
Sensor
Sensor
Sink
Sensor
Sensor
CSMA
S-MAC - sink
WiseMAC-HA - sensor
Ideal - sink
S-MAC - sensor
Ideal - sensor
5 sensor devices
16 bytes data packets
4 bytes Ack messages
FM-UWB (250 kbps)‏
8 mW Rx
4 mW Tx
Sink power consumption higher than sensors because of asymetry
CSMA high power consumption acceptable for the sink but not for the sensors.
WiseMAC power consumption is close to the optimum, but the protocol is throughput limited.
S-MAC power consumption is also throughput limited.
Conclusion: WiseMAC-HA allows to trade between energy and throughput at run-time.
Transition: What about latency ?
WiseMAC
Jérôme Rousselot, CSEM
<author>, <company>

12. doc.: IEEE 802.15-<doc#>
<month year>
doc.: IEEE <doc#>
July 2008
Latency
Sensor
Sensor
Sensor
Sink
Sensor
Sensor
100 25 10 5
Traffic limited,
not device limited
WiseMAC
100 25 10 5
The lines on this figure show an upper bound (95%) on packet latency.
WiseMAC-HA is two orders of magnitude more reactive than state of the art ULP protocols.
WiseMAC-HA allows much higher throughputs and a more efficient use of bandwidth than ULP protocols.
Conclusion: WiseMAC-HA allows to trade between power consumption and latency at run-time.
CSMA
Jérôme Rousselot, CSEM
<author>, <company>

13. doc.: IEEE 802.15-<doc#>
<month year>
doc.: IEEE <doc#>
July 2008
Conclusions
WiseMAC-HA
Robust and reliable: Detect-and-Avoid interferers
Ultra Low Power for all nodes: no need to synchronize
Scalable: traffic limited
Coexistence: the protocol’s fairness allows simultaneous operation of independent networks
Throughput and Latency vs. Energy trade-off
Flexibility to decide mode changes
Flexibility to accomodate other operating modes
Jérôme Rousselot, CSEM
<author>, <company>