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S. Coleri, A. Puri and P. Varaiya

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PEDS September 18, 2006. Power Efficient System for Sensor Networks. 1 ... PEDS September 18, 2006. Power Efficient System for Sensor Networks. 8. Previous Work ... – PowerPoint PPT presentation

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Title: S. Coleri, A. Puri and P. Varaiya


1
Power Efficient System for Sensor Networks
  • S. Coleri, A. Puri and P. Varaiya
  • UC Berkeley
  • Eighth IEEE International Symposium on Computers
    and Communications (ISCC03)
  • PEDS Seminar
  • Presenter Bob Kinicki

2
Outline
  • Introduction to Wireless Sensor Networks
  • Previous Work
  • The Berkeley System
  • Simulation Results
  • Conclusions

3
Wireless Sensor Networks
  • Sensors small devices with low-power
    transmissions and energy limitations (e.g.,
    battery lifetime concerns)
  • The main distinction from traditional wireless
    networks is that the data traffic originates at
    the sensor node and is sent upstream towards
    the access point (AP) that collects the data.
  • While the nature of data collection at the sensor
    is likely to be event driven, for robustness, the
    generation of sensor packets should be periodic
    if possible.

4
Power Consumption Components
  • Primary source of power consumption is the radio
    transmitting, receiving and listening.
  • Key tenet of this paper
  • Sensor nodes must only be awake to receive
    packets destined to themselves or to transmit. At
    all other times, the sensors need to sleep to
    conserve power.

5
The Goal
  • A system for sensor networks that
  • achieves power efficiency in a robust
  • and adaptive manner.

6
Previous Work Contention Based
  • A separate wake-up radio (channel) to power up
    and down the normal channel
  • The key idea is that the wake-up listen mode is
    ultra-low power.
  • Uses a wake-up beacon.
  • S-MAC (sensor MAC)
  • Uses RTS/CTS such that interfering node goes to
    sleep upon overhearing either an RTS or CTS.
  • Problems Here??

7
Previous Work Contention Based
  • STEM (Sparse Topology and Energy Management)
    trades energy savings for latency through
    listen/sleep modes.
  • Uses a separate paging channel.
  • Sending node must first poll the target node by
    sending a wake-up message over the paging
    channel.
  • Target receiving node would then turn on primary
    radio channel to receive regular transmission.
  • This scheme prevents collisions between polling
    and data transmissions.
  • This scheme is effective only for sensor
    scenarios where the sensor spends most of its
    time waiting for events to happen!

8
Previous Work TDMA Based
  • TDMA schemes eliminate overhearing, collisions
    and idle listening.
  • However, proposed TDMA schemes require dealing
    with communication clusters.
  • One solution a high power AP that can
    accomplish all the TDMA scheduling.

9
The Berkeley System
AP
AP
AP
sensor
sensor
Multiple hop tree topology
sensor
sensor
sensor
sensor
sensor
sensor
sensor
sensor
10
The Berkeley System
AP
AP
AP
sensor
sensor
AP range
sensor
sensor
sensor
sensor
Sensor range
sensor
sensor
sensor
sensor
11
Sensor Hardware
  • UCB Mica motes
  • Support adjusting transmission power
  • Sensors run on AA batteries that can supply
    2200mAh at 3V.

12
Three Transmission Ranges
  • Long used for coordination AP frames and
    reaches all the sensors in one hop.
  • Short used to transmit data packets from sensor
    nodes to the AP.
  • Key idea choose the lowest possible range that
    still assures network connectivity.
  • Medium used in tree construction to learn the
    interferers of each sensor node, namely, nodes
    with signal strength too weak to be decoded but
    strong enough to interfere.

13
Three Communication Phases
  • Topology Learning Phase
  • Topology Collecting Phase
  • Scheduling Phase

14
Topology Learning Phase
  • During this phase each node identifies
    interferers, neighbors and parent.
  • AP transmits the topology learning packet
  • current time, incoming packet time over
    longest range in one hop to all sensor nodes the
    AP will coordinate.
  • AP floods the tree construction packet hop
    count over the medium range.

15
Topology Learning Phase
  • Random access scheme is used with an interfering
    threshold to decide on neighbors, interferers and
    the parent on the smallest hop path to the AP.

16
Topology Collection Phase
  • By the end of this phase, the AP has received
    complete topology information.
  • AP transmits the topology collection packet
    current time, incoming packet time over the
    longest range at the announced time.
  • Each node transmits its topology packet parent,
    neighbors, interferers. Vague scheme used is
    CSMA with implicit ACK.

17
Scheduling Phase
  • Sensor node transmissions are explicitly
    scheduled by AP based on complete topology
    information.
  • The AP announces the TDMA schedule by sending the
    time-slotted scheduling packet current time,
    incoming packet time by broadcasting over the
    longest range.
  • Scheduling algorithm can vary.
  • Using a threshold for percentage of successfully
    scheduled sensor nodes, the idea is to keep the
    system in the scheduling phase until the
    percentage falls below the threshold where upon
    the system will switch to the learning phase.
  • High performance comes when the ratio of
    scheduling phases to the other two phases is high.

18
Simulations
  • Used TOSSIM, a TinyOS simulator.
  • Nodes are randomly distributed in circular area.
  • Transmission rate 50 kbps
  • 10 Monte Carlo Simulations
  • Best possible random access result reached by
    adjusting CSMA listening window sizes and the
    backoff settings.

19
Power Consumption Comparisons
  • Assumptions
  • Clock interrupt every millisecond (1ms.)
  • Sensor sampled once per packet generation period
    (30 seconds).

20
Random Access versus TDMA
Battery Lifetimes Random access 10
days Berkeley TDMA scheme 2 years
21
Random Access versus TDMA
  • Listening takes power!
  • Random access yields
  • retransmissions.
  • Overhearing affects
  • reception power.

22
Varying Sensor Sampling Rates
The slope is less than one due to the high power
cost associated with clock interrupts.
23
Redundant Sensor Nodes
The important assumption with redundant sensor
nodes and TDMA is that sharing of the scheduled
slot allows redundant not-scheduled nodes to
reduce their clocking rate and then increase it
back during the last part of the packet
generation period.
24
Conclusions
  • IF Access Point is not power limited then
    asymmetric transmission power between AP and
    sensor nodes is a good idea.
  • Base on ONLY simulations, the Berkeley System
    with TDMA consumes much less power compared to
    random access.
  • Redundant sensor groups also has potential to
    save sensor power in the Berkeley System.
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