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Bing Wang, Wei Wei, Hieu Dinh, Wei Zeng, Krishna R. Pattipati (Fellow IEEE) IEEE Transactions on Mobile Computing, March 2012
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Introduction Problem Setting and Goal Optimal Sequential Testing Heuristic Sequential Testing Schemes ◦ Ordering Algorithm ◦ Greedy Algorithm Performance Evaluation Conclusions
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Wireless sensor networks have been deployed in a wide range of applications. A deployed sensor network may suffer from many network-related faults, e.g., malfunctioning or lossy nodes or links. These faults affect the normal operation of the network, and hence should be detected localized and corrected/repairs.
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Two categories exist in literature ◦ Active Measurement ◦ Passive Measurement
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Active Measurement ◦ A node needs to monitor itself or its neighbors, and transmit the monitoring results locally or to a centralized server. ◦ Advantages Exactly pinpoint the faults. ◦ Drawback Consume precious resources of sensor nodes Reduce the lifetime of the network.
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Passive Measurement ◦ Uses existing end-to-end data inside networks: if end-to-end data indicate faulty end-to-end behaviors, then some components in the network must be faulty. ◦ Advantage No additional traffic into the network ◦ Drawback It poses the challenge of fault inference-accurate inference from end-to-end data.
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Motivated by the complementary strengths of active and passive measurements, the authors propose an approach ◦ Using active measurement to resolve ambiguity in passive measurements ◦ Using passive measurement to guide active measurements to reduce expected testing cost
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Consider a sensor network where sensed data are sent from sources to a sink. The amount of end-to-end data can be used to detect faults in the network. The goal of this paper is to localize persistently lossy links that are used in routing.
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The status of a component can be tested through active measurements. The test incurs a testing cost ◦ The personnel wages when human is involved ◦ The resources used at a sensor node to monitor itself and neighboring nodes/links ◦ The energy and network bandwidths used to transfer the monitoring results to the sink
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A link is lossy or not based on its average loss rate or reception rate. The threshold, t l, can clearly separate good and bad links.
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Complete path information ◦ Know the path used by a source at any point of time Probabilistic path information ◦ Only know the set of paths that are used by a source and the probability using each path
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The authors define path reception rate as the probability that a packet traverses a path successfully. ◦ When n data packets are transmitted along a path and m packets are received successfully, the path reception rate is estimated as m/n.
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Using end-to-end data, we have narrowed down the potential lossy links to the set of links that are used by bad paths/pairs, excluding those used by good paths/pairs. Testing cost
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An optimal solution to the sequential testing problem is one that leads to the minimum expected total test cost The goal of this paper ◦ To minimize expected testing cost The authors also proved the sequential testing problem is NP-hard problem.
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For a given instance of the optimal sequential testing problem, I The recursive equation: the minimum expected testing cost the testing cost of link l k the prior probability that link l k is lossy I kb is the resultant instance when l k is found to be lossy I kg is the resultant instance when l k is found to be good
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P1P1 P2P2 Expected testing cost: c 1
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P1P1 P2P2 Expected testing cost: c 3 + (1-p 3 )*(c 1 + c 2 )
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Two heuristic schemes are proposed in this paper. ◦ Ordering Algorithm ◦ Greedy Algorithm
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In each step, this algorithm picks the link with the highest n k p k /c k to test, ◦ where n k is the number of paths that use link l k
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4 paths: P 1 =(l 2, l 1 ) P 2 =(l 3, l 1 ) P 3 =(l 4, l 1 ) P 4 =(l 5 ) If we know complete path information l 1, l 2, l 3, l 4 l1l1 l 2, l 3, l 4 l1l1 G B nkpk/cknkpk/ck
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If we know probabilistic path information 3 bad pairs: P 1 =(l 2, l 1 ) P 2 =(l 3, l 1 ) P 3 =(l 4, l 1, l 5 )
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In each step, this algorithm picks the link that provides the highest gain. The gain from knowing the status of a link is defined as the cost savings subtracted by the testing cost of this link.
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If we know the complete path information 4 paths: P 1 =(l 2, l 1 ) P 2 =(l 3, l 1 ) P 3 =(l 4, l 1 ) P 4 =(l 5 )
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If we know the probabilistic path information 3 bad pairs: P 1 =(l 2, l 1 ) P 2 =(l 3, l 1 ) P 3 =(l 4, l 1, l 5 )
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The complexity of the ordering algorithm is O(| L | 2 | P |) The complexity of the greedy algorithm is O(| L | 3 | P |) In some special topology cases, the greedy scheme leads to optimal solutions while the greedy scheme may not.
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The network is deployed in a 10unit X 10unit square. A single sink is deployed at the center. 500 nodes are deployed in the square. The transmission range of each node is 3 units. At a given point of time, the paths from the sources to the sink form a reversed tree.
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The exhaustive inspection approach infers in parallel a set of potential faulty components from end-to-end measurements, tests each identified component, and repairs the faulty ones at the end of the iteration.
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The authors formulated an optimal sequential testing problem that carefully combines active and passive measurements for fault localization in WSN. The authors proposed a recursive approach and two heuristic algorithms to solve it.
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