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1 Wireless Sensor Networks: Coverage and Energy Conservation Issues 國立交通大學 資訊工程系 曾煜棋教授 Prof. Yu-Chee Tseng
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2 Research Issues in Sensor Networks Hardware (2000) CPU, memory, sensors, etc. Protocols (2002) MAC layers Routing and transport protocols Applications (2004) Localization and positioning applications Management (2008) Coverage and connectivity problems Coverage and connectivity problems Power management Power management etc. etc.
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3 Coverage Problems In general Determine how well the sensing field is monitored or tracked by sensors. Possible Approaches Geometric Problems Level of Exposure Area Coverage Coverage Coverage and Connectivity Coverage-Preserving and Energy-Conserving Problem
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4 Review: Art Gallery Problem Place the minimum number of cameras such that every point in the art gallery is monitored by at least one camera.
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5 Review: Circle Covering Problem Given a fixed number of identical circles, the goal is to minimize the radius of circles.
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6 Level of Exposure Breach and support paths paths on which the distance from any point to the closest sensor is maximized and minimized Voronoi diagram and Delaunay triangulation Exposure paths Consider the duration that an object is monitored by sensors
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7 Coverage and Connectivity Extending the coverage such that connectivity is maintained. A region is k-covered, then the sensor network is k-connected if R C 2R S
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8 Coverage-Preserving and Energy- Conserving Protocols Sensors' on-duty time should be properly scheduled to conserve energy. This can be done if some nodes share the common sensing region. Question: Which sensors below can be turned off?
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9 The Coverage Problems in 2D Spaces (ACM MONET, 2005)
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10 Coverage Problems In general To determine how well the sensing field is monitored or tracked by sensors Sensors may be randomly deployed
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11 Coverage Problems We formulate this problem as Determine whether every point in the service area of the sensor network is covered by at least a sensors This is called “ sensor a– coverage problem ”. Why sensors? Fault tolerance, quality of service applications: localization, object tracking, video surveillance
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12 The 2D Coverage Problem So this area is not 1-covered! 1-covered means that every point in this area is covered by at least 1 sensor 2-covered means that every point in this area is covered by at least 2 sensors This region is not covered by any sensor! Is this area 1- covered? This area is not only 1-covered, but also 2-covered! What is the coverage level of this area? Coverage level = means that this area is -covered
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13 Sensing and Communication Ranges 1 Honghai Zhang and Jennifer C. Hou, ``On deriving the upper bound of -lifetime for large sensor networks,'' Proc. ACM Mobihoc 2004, June 2004
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14 Assumptions Each sensor is aware of its geographic location and sensing radius. Each sensor can communicate with its neighbors. Difficulties: There are an infinite number of points in any small field. A better way: O(n 2 ) regions can be divided by n circles How to determine all these regions?
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15 The Proposed Solution perimeter We try to look at how the perimeter of each sensor ’ s sensing range is covered. How a perimeter is covered implies how an area is covered … by the continuity of coverage of a region perimeter coverage coverage of an area By collecting perimeter coverage of each sensor, the level of coverage of an area can be determined. a distributed solution
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16 How to calculate the perimeter cover of a sensor? S i is 2- perimeter- covered
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17 Relationship between k-covered and k- perimeter-covered k-covered k-perimeter-covered THEOREM. Suppose that no two sensors are located in the same location. The whole network area A is k-covered iff each sensor in the network is k-perimeter-covered.
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18 Detailed Algorithm Each sensor independently calculates its perimeter-covered. k = min{each sensor ’ s perimeter coverage} Time complexity: nd log(d) n: number of sensors d: number of neighbors of a sensor
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19 Simulation Results
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20 A Toolkit
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21 Summary An important multi-level coverage problem! We have proposed efficient polynomial- time solutions. Simulation results and a toolkit based on proposed solutions are presented.
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22 The Coverage Problem in 3D Spaces (IEEE Globecom 2004)
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23 The 3D Coverage Problem What is the coverage level of this 3D area?
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24 The 3D Coverage Problem Problem Definition Given a set of sensors in a 3D sensing field, is every point in this field covered by at least a sensors? Assumptions: Each sensor is aware of its own location as well as its neighbors ’ locations. The sensing range of each sensor is modeled by a 3D ball. The sensing ranges of sensors can be non- uniform.
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25 Overview of Our Solution The Proposed Solution We reduce the geometric problem from a 3D space to one in a 2D space, and then from a 2D space to one in a 1D space.
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26 Reduction Technique (I) 3D => 2D To determine whether the whole sensing field is sufficiently covered, we look at the spheres of all sensors Theorem 1: If each sphere is -sphere- covered, then the sensing field is -covered. Sensor s i is-sphere-covered if all points on its sphere are sphere-covered by at least sensors, i.e., on or within the spheres of at least sensors.
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27 Reduction Technique (II) 2D => 1D To determine whether each sensor ’ s sphere is sufficiently covered, we look at how each spherical cap and how each circle of the intersection of two spheres is covered. (refer to the next page) Corollary 1: Consider any sensor s i. If each point on S i is -cap-covered, then sphere S i is -sphere-covered. A point p is -cap-covered if it is on at least caps.
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28 Cap and Circle
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29 k-cap-covered p is 2-cap-covered (by Cap(i, j) and Cap(i, k)).
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30 Reduction Technique (III) 2D => 1D Theorem 2: Consider any sensor s i and each of its neighboring sensor s j. If each circle Cir(i, j) is -circle-covered, then the sphere S i is - cap-covered. A circle is -circle-covered if every point on this circle is covered by at least caps.
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31 k-circle-covered Cir(i, j) is 1-circle-covered (by Cap(i, k)). Cir(i, j) Cap(i, k)
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32 Reduction Technique (IV) 2D => 1D By stretching each circle on a 1D line, the level of circle coverage can be easily determined. This can be done by our 2-D coverage solution.
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33 Reduction Example =>
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34 Reduction Example =>
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35 Calculating the Circle Coverage
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36 Calculating the Circle Coverage =>
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37 Calculating the Circle Coverage =>
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38 Calculating the Circle Coverage =>
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39 The Complete Algorithm Each sensor s i independently calculates the circle coverage of each of the circle on its sphere. sphere coverage of s i = min{ circle coverage of all circles on S i } overall coverage = min{ sphere coverage of all sensors }
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40 Complexity To calculate the sphere coverage of one sensor: O(d 2 logd) d is the maximum number of neighbors of a sensor Overall: O(nd 2 logd) n is the number of sensors in this field
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41 Short Summary We define the coverage problem in a 3D space. Proposed solution 3D => 2D => 1D Network Coverage => Sphere Coverage => Circle Coverage Applications Deploying sensors Reducing on-duty time of sensors
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42 A Decentralized Energy-Conserving, Coverage-Preserving Protocol (IEEE ISCAS 2005)
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43 Overview Goal: prolong the network lifetime Schedule sensors ’ on-duty time Put as many sensors into sleeping mode as possible Meanwhile active nodes should maintain sufficient coverage Two protocols are proposed: basic scheme (by Yan, He, and Stankovic, in ACM SenSys 2003) energy-based scheme (by Tseng, IEEE ISCAS 2005)
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44 Basic Scheme Two phases Initialization phase: Message exchange working schedule Calculate each sensor ’ s working schedule in the next phase Sensing phase: This phase is divided into multiple rounds. working schedule. In each round, a sensor has its own working schedule. Reference time: Each sensor will randomly generate a number in the range [0, cycle_length] as its reference time. Each sensor will randomly generate a number in the range [0, cycle_length] as its reference time.
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45 Structure of Sensors ’ Working Cycles Theorem: If each intersection point between any two sensors ’ boundaries is always covered, then the whole sensing field is always covered. Basic Idea: Each sensor i and its neighbors will share the responsibility, in a time division manner, to cover each intersection point.
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46 a b c d An Example (to calculate sensor a ’ s working schedule) Sensing phaseInitial phase Round 1Round 2 ……… Round n Initial phase 聯集 : a ’ s final on-duty time in round i Round i Ref aRef bRef c Ref d
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47 more details … The above will also be done by sensors b, c, and d. This will guarantee that all intersection points of sensors ’ boundaries will be covered over the time domain.
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48 Energy-Based Scheme goal: based on remaining energy of sensors Nodes with more remaining energies should work longer. Each round is logically separated into two zones: larger zone: 3T/4 smaller zone: T/4. Reference time selection: If a node ’ s remaining energy is larger than ½ of its neighbors ‘, randomly choose a reference time in the larger zone. Otherwise, choose a reference time in the smaller zone. Work schedule selection: based on energy (refer to the next page)
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49 Energy-Based Scheme (cont.) Front p,i and Back p,i are also selected based on remaining energies. Round i Ref aRef bRef c Ref d richer rich poor
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50 Two Enhancements k-Coverage-Preserving Protocol (omitted) active time optimization Longest Schedule First (LSF) Shortest Lifetime First (SLF)
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51 Simulation Results
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52 Simulation Results (cont.)
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53 Summary A distributed node-scheduling protocol Conserve energy Preserve coverage Handle k-coverage problem Advantage Distribute energy consumption among nodes
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54 Conclusions a survey of solutions to the coverage problems Both in 2D and 3D spaces a survey of solutions to coverage- preserving, energy-conserving problems Fairly distribute sensors ’ energy expenditure
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55 References 1. C.-F. Huang and Y.-C. Tseng, “ The Coverage Problem in a Wireless Sensor Network ”, ACM Mobile Networking and Applications (MONET), Special Issue on Wireless Sensor Networks. 2. C.-F. Huang and Y.-C. Tseng, “ A Survey of Solutions to the Coverage Problems in Wireless Sensor Networks ”, Journal of Internet Technology, Special Issue on Wireless Ad Hoc and Sensor Networks. 3. C.-F. Huang and Y.-C. Tseng, “ The Coverage Problem in a Wireless Sensor Network ”, ACM Int ’ l Workshop on Wireless Sensor Networks and Applications (WSNA) (in conjunction with ACM MobiCom), 2003. 4. C.-F. Huang, Y.-C. Tseng, and Li-Chu Lo, “ The Coverage Problem in Three-Dimensional Wireless Sensor Networks ”, IEEE GLOBECOM, 2004. 5. C.-F. Huang, L.-C. Lo, Y.-C. Tseng, and W.-T. Chen, “ Decentralized Energy-Conserving and Coverage-Preserving Protocols for Wireless Sensor Networks ”, Int ’ l Symp. on Circuits and Systems (ISCAS), 2005.
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