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ENERGY EFFICIENT INDOOR LOCALIZATION IN WIRELESS SENSOR NETWORKS
Ph.D Student: Sadaf TANVIR Co-Supervisor: Benoît PONSARD Supervisor: Andrzej Duda Insert compass image Sadaf Tanvir-INPG 2007
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Localization in WSNs To achieve Better interpretation of sensed data
Inventory monitoring Environment/forest monitoring Smart battlefield To achieve Better interpretation of sensed data Quality of network coverage Geographic Routing Target movement Monitoring Machine survillance Smart hospital Capability of WSNs to self organize Soil moisture monitoring system at Camalie Vineyards California Courtesy: Sadaf Tanvir-INPG 2007
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Contents Introduction Preliminary Work Conceived steps of future work
Localization using: Beacon approach Beaconless approach Conceived steps of future work Sadaf Tanvir-INPG 2007
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Introduction Types of localization processes: Intrinsic Extrinsic
-Endogenous process -Exogenous process Extrinsic more approapriate for WSN Coordinate system Absolute Relative Sadaf Tanvir-INPG 2007
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Related work Localization approaches: Exogenous systems
Active badge Active bat RADAR Endogenous systems Cricket GPS based. GPS less GPS-less: Netwide wide coherence(Relative coordinate system) GPS-based: A percentage of networks nodes know their position: Anchor nodes (Absolute coordinate system) Sadaf Tanvir-INPG 2007
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Our focus GPS based localization process involving:
Anchor/beacon nodes Unlocalized/free/unknown/blindfolded nodes Unlocalized Nodes Anchor Nodes Sadaf Tanvir-INPG 2007
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Collaborative Process
The Process 1D Measurement Position Refinement MAC 2-3D Local Process Collaborative Process Sadaf Tanvir-INPG 2007
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1D Measurement Range free method Range based method
2 Techniques of Distance Measurement: Range free method For achieving coarse grained accuracy 3 methods of distance estimation Sum-Dist DV-hop Euclidean Range based method For fine grained accuracy TOA/TOF TDOA RSSI AOA Sadaf Tanvir-INPG 2007
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Ranging Implementation
Ultrasound Radio frequency Many others RF TOF -Provides long range -Good wall penetration -No additional hardware required -Pair wise roundtrip TOF do not require clock synchronization -Ranging accuracy is reported to be between 1-3m(rms) -To pave way for Ultra wide band(UWB) systems (infrared,Laser, Bluetooth, ,RFID) Nonradio frquency Communication Optical medium Sadaf Tanvir-INPG 2007
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2-3D Local Process Coversion of 1D distances in 2-3D coordinates
If range-free 1D techniques are used Centriod/proximity DV-hop Amporphous Positioning Approximate Point in Triangulation If range based 1D techniques are used Trilateration Maximum Likelihood/Minimum Least Squares Many others Taxonomy of techniques available for position estimation from 1D distance measurement Sadaf Tanvir-INPG 2007
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Collaborative Process
Iterative propagation of information across the network through collaboration of neighboring nodes Enables each unlocalized node of the network to calculate its position 5 1 4 3 6 2 Sadaf Tanvir-INPG 2007
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Collaborative Process
Position Refinement Causes of errors in pair wise TOF Interference, obstruction and multipath fading Clock drift Two kinds of errors Ranging errors Localization errors 1D Measurement 2-3D Local Process Collaborative Process MAC Position Refinement Sadaf Tanvir-INPG 2007
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Indoor Localization Active Research Area More difficult
GPS signals not available Signals are affected by walls, furniture, people Reflection, refraction, diffraction and scattering cause interference of RF signals Sadaf Tanvir-INPG 2007
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Collaborative Process
Energy Consumption Major source of energy consumption The radio transceiver 1D measurement Position refinement MAC 2-3D local Process Collaborative Process Sadaf Tanvir-INPG 2007
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Our Objectives Design and evaluate indoor WSN localization techniques that are energy efficient To evaluate the Accuracy vs. Energy Consumption trade-off of our suggested approaches Sadaf Tanvir-INPG 2007
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Preliminary work Understanding the localization phenomenon
Localization using: Beacon messages Beaconless approach Sadaf Tanvir-INPG 2007
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Beacon Approach(1/2) based on the work of L. De Nardis and M. -G
Beacon Approach(1/2) based on the work of L. De Nardis and M.-G. Di Benedetto UN gathers BMs from the three ANs BM from AN1 BM from AN2 BM from AN3 AN1 AN2 AN3 UN AN: Anchor node UN: Unlocalized node ANs receive Query message and reply with a unicast response message (RM) ANs broadcast beacon messages(BM) UN Broadcasts Query message(QM) UN estimates 1D distance between itself and the anchor nodes Sadaf Tanvir-INPG 2007
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Beacon Approach(2/2) The UN only broadcasts QM when there is
Pros The UN only broadcasts QM when there is surety of getting 1D measurement through 2 way ranging process Addition of new nodes is easy Cons Constant emission of BM RM emission by LN on its scheduled time highly unsuitable for the 2 way ranging process. Sadaf Tanvir-INPG 2007
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Simulation Results Energy consumption measured as the no. of messages exchanged Node degree(η) =14 Sadaf Tanvir-INPG 2007
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Beaconless Approach(1/2)
AN3 UN AN: Anchor node UN: Unlocalized node AN2 UN starts the process by broadcasting Query message(QM) AN1 ANs receive Query message and reply with a unicast response message (RM) UN estimates 1D distance between itself and the anchor nodes Sadaf Tanvir-INPG 2007
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Beaconless Approach(2/2)
Pros Energy not wasted in broadcasting Beacon messages RM emission by LN: a reaction to the QM making 1D measurement possible Addition of new nodes is easy once the network has converged Cons Redundant QM emission from UNs far from the Anchor group Sadaf Tanvir-INPG 2007
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Simulation Results Node degree(η) =14 Sadaf Tanvir-INPG 2007
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Comparison of Beacon vs. Beaconless approach
Convergence Latency Sadaf Tanvir-INPG 2007
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Tx/Rx messages Sadaf Tanvir-INPG 2007
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Scope of Current Work Only analyses MAC level message exchange
1D measurement Position Refinement MAC 2-3D local Process Collaborative Process Sadaf Tanvir-INPG 2007
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Drawback of Current Approach
Information propagation over a large number of hops Error accumulation and poor accuracy Sadaf Tanvir-INPG 2007
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Collaborative Process
Future work Step 1: Study AN placement in the network Its effect on: Accuracy of location estimation Communication cost Convergence latency 1D measurement 2-3D local Process Collaborative Process MAC Position refinement Sadaf Tanvir-INPG 2007
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Future work Step 2: Study and analyse the energy consumption during collaborative process 1D measurement Position Refinement MAC Through the use of Robust least squares 2-3D local Process Collaborative Process Sadaf Tanvir-INPG 2007
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Future work Study comunication cost, convergence latency and accuracy w.r.t AN placement in the network Implement the RLS approach and evaluate it in terms of Accuracy achieved vs. Energy consumed Evaluate our suggested approach on energy efficient MAC protocol designed for WSNs and realistic indoor propagation models Direct my work towards application oriented localization e.g. Localization for geographic routing To evaluate the accuracy vs. Energy trade-off Sadaf Tanvir-INPG 2007
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THANK YOU! Questions Comments Feed back Critique 17-10-07
Sadaf Tanvir-INPG 2007
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