2 \documentclass[conference]{IEEEtran}
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37 \title{Energy-Efficient Activity Scheduling in Heterogeneous Energy Wireless Sensor Networks}
39 % author names and affiliations
40 % use a multiple column layout for up to three different
42 \author{\IEEEauthorblockN{Ali Kadhum Idrees, Karine Deschinkel, Michel Salomon, and Rapha\"el Couturier }
43 \IEEEauthorblockA{FEMTO-ST Institute, UMR 6174 CNRS, University of Franche-Comte, Belfort, France \\
44 Email: ali.idness@edu.univ-fcomte.fr, $\lbrace$karine.deschinkel, michel.salomon, raphael.couturier$\rbrace$@univ-fcomte.fr}
45 %\email{\{ali.idness, karine.deschinkel, michel.salomon, raphael.couturier\}@univ-fcomte.fr}
47 %\IEEEauthorblockN{Homer Simpson}
48 %\IEEEauthorblockA{FEMTO-ST Institute, UMR CNRS, University of Franche-Comte, Belfort, France}
50 %\IEEEauthorblockN{James Kirk\\ and Montgomery Scott}
51 %\IEEEauthorblockA{FEMTO-ST Institute, UMR CNRS, University of Franche-Comte, Belfort, France}
57 One of the fundamental challenges in Wireless Sensor Networks (WSNs)
58 is coverage preservation and extension of the network lifetime
59 continuously and effectively when monitoring a certain area (or
60 region) of interest. In this paper a coverage optimization protocol to
61 improve the lifetime in heterogeneous energy wireless sensor networks
62 is proposed. The area of interest is first divided into subregions
63 using a divide-and-conquer method and then scheduling of sensor node
64 activity is planned for each subregion. The proposed scheduling
65 considers rounds during which a small number of nodes, remaining
66 active for sensing, is selected to ensure coverage. Each round
67 consists of four phases: (i)~Information Exchange, (ii)~Leader
68 Election, (iii)~Decision, and (iv)~Sensing. The decision process is
69 carried out by a leader node which solves an integer program.
70 Simulation results show that the proposed approach can prolong the
71 network lifetime and improve the coverage performance.
74 %\keywords{Area Coverage, Wireless Sensor Networks, lifetime Optimization, Distributed Protocol.}
76 \IEEEpeerreviewmaketitle
78 \section{Introduction}
80 \noindent Recent years have witnessed significant advances in wireless
81 communications and embedded micro-sensing MEMS technologies which have
82 made emerge wireless sensor networks as one of the most promising
83 technologies~\cite{asc02}. In fact, they present huge potential in
84 several domains ranging from health care applications to military
85 applications. A sensor network is composed of a large number of tiny
86 sensing devices deployed in a region of interest. Each device has
87 processing and wireless communication capabilities, which enable to
88 sense its environment, to compute, to store information and to deliver
89 report messages to a base station.
90 %These sensor nodes run on batteries with limited capacities. To achieve a long life of the network, it is important to conserve battery power. Therefore, lifetime optimisation is one of the most critical issues in wireless sensor networks.
91 One of the main design issues in Wireless Sensor Networks (WSNs) is to
92 prolong the network lifetime, while achieving acceptable quality of
93 service for applications. Indeed, sensor nodes have limited resources
94 in terms of memory, energy and computational power.
96 Since sensor nodes have limited battery life and without being able to
97 replace batteries, especially in remote and hostile environments, it
98 is desirable that a WSN should be deployed with high density because
99 spatial redundancy can then be exploited to increase the lifetime of
100 the network. In such a high density network, if all sensor nodes were
101 to be activated at the same time, the lifetime would be reduced. To
102 extend the lifetime of the network, the main idea is to take benefit
103 from the overlapping sensing regions of some sensor nodes to save
104 energy by turning off some of them during the sensing phase.
105 Obviously, the deactivation of nodes is only relevant if the coverage
106 of the monitored area is not affected. Consequently, future software
107 may need to adapt appropriately to achieve acceptable quality of
108 service for applications. In this paper we concentrate on area
109 coverage problem, with the objective of maximizing the network
110 lifetime by using an adaptive scheduling. The area of interest is
111 divided into subregions and an activity scheduling for sensor nodes is
112 planned for each subregion.
113 In fact, the nodes in a subregion can be seen as a cluster where
114 each node sends sensing data to the cluster head or the sink node.
115 Furthermore, the activities in a subregion/cluster can continue even
116 if another cluster stops due to too much node failures.
117 Our scheduling scheme considers rounds, where a round starts with a
118 discovery phase to exchange information between sensors of the
119 subregion, in order to choose in suitable manner a sensor node to
120 carry out a coverage strategy. This coverage strategy involves the
121 solving of an integer program which provides the activation of the
122 sensors for the sensing phase of the current round.
124 The remainder of the paper is organized as follows. The next section
126 reviews the related work in the field. Section~\ref{pd} is devoted to
127 the scheduling strategy for energy-efficient coverage.
128 Section~\ref{cp} gives the coverage model formulation which is used to
129 schedule the activation of sensors. Section~\ref{exp} shows the
130 simulation results obtained using the discrete event simulator on
131 OMNET++ \cite{varga}. They fully demonstrate the usefulness of the
132 proposed approach. Finally, we give concluding remarks and some
133 suggestions for future works in Section~\ref{sec:conclusion}.
135 \section{Related Works}
138 \noindent This section is dedicated to the various approaches proposed
139 in the literature for the coverage lifetime maximization problem,
140 where the objective is to optimally schedule sensors' activities in
141 order to extend network lifetime in a randomly deployed network. As
142 this problem is subject to a wide range of interpretations, we suggest
143 to recall main definitions and assumptions related to our work.
146 %\item Area Coverage: The main objective is to cover an area. The area coverage requires
147 %that the sensing range of working Active nodes cover the whole targeting area, which means any
148 %point in target area can be covered~\cite{Mihaela02,Raymond03}.
150 %\item Target Coverage: The objective is to cover a set of targets. Target coverage means that the discrete target points can be covered in any time. The sensing range of working Active nodes only monitors a finite number of discrete points in targeting area~\cite{Mihaela02,Raymond03}.
152 %\item Barrier Coverage An objective to determine the maximal support/breach paths that traverse a sensor field. Barrier coverage is expressed as finding one or more routes with starting position and ending position when the targets pass through the area deployed with sensor nodes~\cite{Santosh04,Ai05}.
156 The most discussed coverage problems in literature can be classified
157 into two types \cite{ma10}: area coverage (also called full or blanket
158 coverage) and target coverage. An area coverage problem is to find a
159 minimum number of sensors to work such that each physical point in the
160 area is within the sensing range of at least one working sensor node.
161 Target coverage problem is to cover only a finite number of discrete
162 points called targets. This type of coverage has mainly military
163 applications. Our work will concentrate on the area coverage by design
164 and implementation of a strategy which efficiently selects the active
165 nodes that must maintain both sensing coverage and network
166 connectivity and in the same time improve the lifetime of the wireless
167 sensor network. But requiring that all physical points of the
168 considered region are covered may be too strict, especially where the
169 sensor network is not dense. Our approach represents an area covered
170 by a sensor as a set of primary points and tries to maximize the total
171 number of primary points that are covered in each round, while
172 minimizing overcoverage (points covered by multiple active sensors
177 Various definitions exist for the lifetime of a sensor
178 network~\cite{die09}. Main definitions proposed in the literature are
179 related to the remaining energy of the nodes or to the percentage of
180 coverage. The lifetime of the network is mainly defined as the amount
181 of time that the network can satisfy its coverage objective (the
182 amount of time that the network can cover a given percentage of its
183 area or targets of interest). In this work, we assume that the network
184 is alive until all nodes have been drained of their energy or the
185 sensor network becomes disconnected, and we measure the coverage ratio
186 during the WSN lifetime. Network connectivity is important because an
187 active sensor node without connectivity towards a base station cannot
188 transmit information on an event in the area that it monitors.
190 {\bf Activity scheduling}
192 Activity scheduling is to schedule the activation and deactivation of
193 sensor nodes. The basic objective is to decide which sensors are in
194 what states (active or sleeping mode) and for how long, such that the
195 application coverage requirement can be guaranteed and the network
196 lifetime can be prolonged. Various approaches, including centralized,
197 distributed, and localized algorithms, have been proposed for activity
198 scheduling. In the distributed algorithms, each node in the network
199 autonomously makes decisions on whether to turn on or turn off itself
200 only using local neighbor information. In centralized algorithms, a
201 central controller (a node or base station) informs every sensors of
202 the time intervals to be activated.
204 {\bf Distributed approaches}
206 Some distributed algorithms have been developed
207 in~\cite{Gallais06,Tian02,Ye03,Zhang05,HeinzelmanCB02} to perform the
208 scheduling. Distributed algorithms typically operate in rounds for
209 predetermined duration. At the beginning of each round, a sensor
210 exchange information with its neighbors and makes a decision to either
211 remain turned on or to go to sleep for the round. This decision is
212 basically based on simple greedy criteria like the largest uncovered
213 area \cite{Berman05efficientenergy}, maximum uncovered targets
214 \cite{1240799}. In \cite{Tian02}, the scheduling scheme is divided
215 into rounds, where each round has a self-scheduling phase followed by
216 a sensing phase. Each sensor broadcasts a message containing node ID
217 and node location to its neighbors at the beginning of each round. A
218 sensor determines its status by a rule named off-duty eligible rule
219 which tells him to turn off if its sensing area is covered by its
220 neighbors. A back-off scheme is introduced to let each sensor delay
221 the decision process with a random period of time, in order to avoid
222 that nodes make conflicting decisions simultaneously and that a part
223 of the area is no longer covered.
224 \cite{Prasad:2007:DAL:1782174.1782218} defines a model for capturing
225 the dependencies between different cover sets and proposes localized
226 heuristic based on this dependency. The algorithm consists of two
227 phases, an initial setup phase during which each sensor computes and
228 prioritize the covers and a sensing phase during which each sensor
229 first decides its on/off status, and then remains on or off for the
230 rest of the duration. Authors in \cite{chin2007} propose a novel
231 distributed heuristic named Distributed Energy-efficient Scheduling
232 for k-coverage (DESK) so that the energy consumption among all the
233 sensors is balanced, and network lifetime is maximized while the
234 coverage requirements is being maintained. This algorithm works in
235 round, requires only 1-sensing-hop-neighbor information, and a sensor
236 decides its status (active/sleep) based on its perimeter coverage
237 computed through the k-Non-Unit-disk coverage algorithm proposed in
238 \cite{Huang:2003:CPW:941350.941367}.
240 Some others approaches do not consider synchronized and predetermined
241 period of time where the sensors are active or not. Indeed, each
242 sensor maintains its own timer and its time wake-up is randomized
243 \cite{Ye03} or regulated \cite{cardei05} over time.
244 %A ecrire \cite{Abrams:2004:SKA:984622.984684}p33
246 %The scheduling information is disseminated throughout the network and only sensors in the active state are responsible
247 %for monitoring all targets, while all other nodes are in a low-energy sleep mode. The nodes decide cooperatively which of them will remain in sleep mode for a certain
250 %one way of increasing lifeteime is by turning off redundant nodes to sleep mode to conserve energy while active nodes provide essential coverage, which improves fault tolerance.
252 %In this paper we focus on centralized algorithms because distributed algorithms are outside the scope of our work. Note that centralized coverage algorithms have the advantage of requiring very low processing power from the sensor nodes which have usually limited processing capabilities. Moreover, a recent study conducted in \cite{pc10} concludes that there is a threshold in terms of network size to switch from a localized to a centralized algorithm. Indeed the exchange of messages in large networks may consume a considerable amount of energy in a localized approach compared to a centralized one.
254 {\bf Centralized approaches}
256 Power efficient centralized schemes differ according to several
257 criteria \cite{Cardei:2006:ECP:1646656.1646898}, such as the coverage
258 objective (target coverage or area coverage), the node deployment
259 method (random or deterministic) and the heterogeneity of sensor nodes
260 (common sensing range, common battery lifetime). The major approach is
261 to divide/organize the sensors into a suitable number of set covers
262 where each set completely covers an interest region and to activate
263 these set covers successively.
265 First algorithms proposed in the literature consider that the cover
266 sets are disjoint: a sensor node appears in exactly one of the
267 generated cover sets. For instance, Slijepcevic and Potkonjak
268 \cite{Slijepcevic01powerefficient} propose an algorithm which
269 allocates sensor nodes in mutually independent sets to monitor an area
270 divided into several fields. Their algorithm builds a cover set by
271 including in priority the sensor nodes which cover critical fields,
272 that is to say fields that are covered by the smallest number of
273 sensors. The time complexity of their heuristic is $O(n^2)$ where $n$
274 is the number of sensors. \cite{cardei02}~describes a graph coloring
275 technique to achieve energy savings by organizing the sensor nodes
276 into a maximum number of disjoint dominating sets which are activated
277 successively. The dominating sets do not guarantee the coverage of the
278 whole region of interest. Abrams et
279 al.~\cite{Abrams:2004:SKA:984622.984684} design three approximation
280 algorithms for a variation of the set k-cover problem, where the
281 objective is to partition the sensors into covers such that the number
282 of covers that include an area, summed over all areas, is maximized.
283 Their work builds upon previous work
284 in~\cite{Slijepcevic01powerefficient} and the generated cover sets do
285 not provide complete coverage of the monitoring zone.
287 %examine the target coverage problem by disjoint cover sets but relax the requirement that every cover set monitor all the targets and try to maximize the number of times the targets are covered by the partition. They propose various algorithms and establish approximation ratio.
289 In~\cite{Cardei:2005:IWS:1160086.1160098}, the authors propose a
290 heuristic to compute the disjoint set covers (DSC). In order to
291 compute the maximum number of covers, they first transform DSC into a
292 maximum-flow problem, which is then formulated as a mixed integer
293 programming problem (MIP). Based on the solution of the MIP, they
294 design a heuristic to compute the final number of covers. The results
295 show a slight performance improvement in terms of the number of
296 produced DSC in comparison to~\cite{Slijepcevic01powerefficient}, but
297 it incurs higher execution time due to the complexity of the mixed
298 integer programming solving. %Cardei and Du
299 \cite{Cardei:2005:IWS:1160086.1160098} propose a method to efficiently
300 compute the maximum number of disjoint set covers such that each set
301 can monitor all targets. They first transform the problem into a
302 maximum flow problem which is formulated as a mixed integer
303 programming (MIP). Then their heuristic uses the output of the MIP to
304 compute disjoint set covers. Results show that these heuristic
305 provides a number of set covers slightly larger compared to
306 \cite{Slijepcevic01powerefficient} but with a larger execution time
307 due to the complexity of the mixed integer programming resolution.
308 Zorbas et al. \cite{Zorbas2007} present B\{GOP\}, a centralized
309 coverage algorithm introducing sensor candidate categorization
310 depending on their coverage status and the notion of critical target
311 to call targets that are associated with a small number of
312 sensors. The total running time of their heuristic is $0(m n^2)$ where
313 $n$ is the number of sensors, and $m$ the number of targets. Compared
314 to algorithm's results of Slijepcevic and Potkonjak
315 \cite{Slijepcevic01powerefficient}, their heuristic produces more
316 cover sets with a slight growth rate in execution time.
317 %More recently Manju and Pujari\cite{Manju2011}
319 In the case of non-disjoint algorithms \cite{Manju2011}, sensors may
320 participate in more than one cover set. In some cases this may
321 prolong the lifetime of the network in comparison to the disjoint
322 cover set algorithms, but designing algorithms for non-disjoint cover
323 sets generally induces a higher order of complexity. Moreover, in
324 case of a sensor's failure, non-disjoint scheduling policies are less
325 resilient and less reliable because a sensor may be involved in more
326 than one cover sets. For instance, Cardei et al.~\cite{cardei05bis}
327 present a linear programming (LP) solution and a greedy approach to
328 extend the sensor network lifetime by organizing the sensors into a
329 maximal number of non-disjoint cover sets. Simulation results show
330 that by allowing sensors to participate in multiple sets, the network
331 lifetime increases compared with related
332 work~\cite{Cardei:2005:IWS:1160086.1160098}. In~\cite{berman04}, the
333 authors have formulated the lifetime problem and suggested another
334 (LP) technique to solve this problem. A centralized provably near
335 optimal solution based on the Garg-K\"{o}nemann
336 algorithm~\cite{garg98} is also proposed.
338 {\bf Our contribution}
340 There are three main questions which should be addressed to build a
341 scheduling strategy. We give a brief answer to these three questions
342 to describe our approach before going into details in the subsequent
345 \item {\bf How must the phases for information exchange, decision and
346 sensing be planned over time?} Our algorithm divides the time line
347 into a number of rounds. Each round contains 4 phases: Information
348 Exchange, Leader Election, Decision, and Sensing.
350 \item {\bf What are the rules to decide which node has to be turned on
351 or off?} Our algorithm tends to limit the overcoverage of points of
352 interest to avoid turning on too much sensors covering the same
353 areas at the same time, and tries to prevent undercoverage. The
354 decision is a good compromise between these two conflicting
357 \item {\bf Which node should make such decision?} As mentioned in
358 \cite{pc10}, both centralized and distributed algorithms have their
359 own advantages and disadvantages. Centralized coverage algorithms
360 have the advantage of requiring very low processing power from the
361 sensor nodes which have usually limited processing capabilities.
362 Distributed algorithms are very adaptable to the dynamic and
363 scalable nature of sensors network. Authors in \cite{pc10} conclude
364 that there is a threshold in terms of network size to switch from a
365 localized to a centralized algorithm. Indeed the exchange of
366 messages in large networks may consume a considerable amount of
367 energy in a localized approach compared to a centralized one. Our
368 work does not consider only one leader to compute and to broadcast
369 the schedule decision to all the sensors. When the network size
370 increases, the network is divided in many subregions and the
371 decision is made by a leader in each subregion.
374 \section{Activity Scheduling}
377 We consider a randomly and uniformly deployed network consisting of
378 static wireless sensors. The wireless sensors are deployed in high
379 density to ensure initially a full coverage of the interested area. We
380 assume that all nodes are homogeneous in terms of communication and
381 processing capabilities and heterogeneous in term of energy provision.
382 The location information is available to the sensor node either
383 through hardware such as embedded GPS or through location discovery
384 algorithms. The area of interest can be divided using the
385 divide-and-conquer strategy into smaller areas called subregions and
386 then our coverage protocol will be implemented in each subregion
387 simultaneously. Our protocol works in rounds fashion as shown in
390 %Given the interested Area $A$, the wireless sensor nodes set $S=\lbrace s_1,\ldots,s_N \rbrace $ that are deployed randomly and uniformly in this area such that they are ensure a full coverage for A. The Area A is divided into regions $A=\lbrace A^1,\ldots,A^k,\ldots, A^{N_R} \rbrace$. We suppose that each sensor node $s_i$ know its location and its region. We will have a subset $SSET^k =\lbrace s_1,...,s_j,...,s_{N^k} \rbrace $ , where $s_N = s_{N^1} + s_{N^2} +,\ldots,+ s_{N^k} +,\ldots,+s_{N^R}$. Each sensor node $s_i$ has the same initial energy $IE_i$ in the first time and the current residual energy $RE_i$ equal to $IE_i$ in the first time for each $s_i$ in A. \\
394 \includegraphics[width=85mm]{FirstModel.eps} % 70mm
395 \caption{Multi-round coverage protocol}
399 Each round is divided into 4 phases : Information (INFO) Exchange,
400 Leader Election, Decision, and Sensing. For each round there is
401 exactly one set cover responsible for sensing task. This protocol is
402 more reliable against the unexpectedly node failure because it works
403 in rounds. On the one hand, if a node failure is detected before
404 taking the decision, the node will not participate to this phase, and,
405 on the other hand, if the node failure occurs after the decision, the
406 sensing task of the network will be affected temporarily: only during
407 the period of sensing until a new round starts, since a new set cover
408 will take charge of the sensing task in the next round. The energy
409 consumption and some other constraints can easily be taken into
410 account since the sensors can update and then exchange their
411 information (including their residual energy) at the beginning of each
412 round. However, the pre-sensing phases (INFO Exchange, Leader
413 Election, Decision) are energy consuming for some nodes, even when
414 they do not join the network to monitor the area. Below, we describe
415 each phase in more detail.
417 \subsection{INFOrmation Exchange Phase}
419 Each sensor node $j$ sends its position, remaining energy $RE_j$, and
420 the number of local neighbors $NBR_j$ to all wireless sensor nodes in
421 its subregion by using an INFO packet and then listens to the packets
422 sent from other nodes. After that, each node will have information
423 about all the sensor nodes in the subregion. In our model, the
424 remaining energy corresponds to the time that a sensor can live in the
427 %\subsection{\textbf Working Phase:}
429 %The working phase works in rounding fashion. Each round include 3 steps described as follow :
431 \subsection{Leader Election Phase}
432 This step includes choosing the Wireless Sensor Node Leader (WSNL)
433 which will be responsible of executing coverage algorithm. Each
434 subregion in the area of interest will select its own WSNL
435 independently for each round. All the sensor nodes cooperate to
436 select WSNL. The nodes in the same subregion will select the leader
437 based on the received information from all other nodes in the same
438 subregion. The selection criteria in order of priority are: larger
439 number of neighbors, larger remaining energy, and then in case of
440 equality, larger index.
442 \subsection{Decision Phase}
443 The WSNL will solve an integer program (see section~\ref{cp}) to
444 select which sensors will be activated in the following sensing phase
445 to cover the subregion. WSNL will send Active-Sleep packet to each
446 sensor in the subregion based on algorithm's results.
447 %The main goal in this step after choosing the WSNL is to produce the best representative active nodes set that will take the responsibility of covering the whole region $A^k$ with minimum number of sensor nodes to prolong the lifetime in the wireless sensor network. For our problem, in each round we need to select the minimum set of sensor nodes to improve the lifetime of the network and in the same time taking into account covering the region $A^k$ . We need an optimal solution with tradeoff between our two conflicting objectives.
448 %The above region coverage problem can be formulated as a Multi-objective optimization problem and we can use the Binary Particle Swarm Optimization technique to solve it.
450 \subsection{Sensing Phase}
451 Active sensors in the round will execute their sensing task to
452 preserve maximal coverage in the region of interest. We will assume
453 that the cost of keeping a node awake (or sleep) for sensing task is
454 the same for all wireless sensor nodes in the network. Each sensor
455 will receive an Active-Sleep packet from WSNL informing it to stay
456 awake or go sleep for a time equal to the period of sensing until
457 starting a new round.
459 %\subsection{Sensing coverage model}
462 %\noindent We try to produce an adaptive scheduling which allows sensors to operate alternatively so as to prolong the network lifetime. For convenience, the notations and assumptions are described first.
463 %The wireless sensor node use the binary disk sensing model by which each sensor node will has a certain sensing range is reserved within a circular disk called radius $R_s$.
464 \noindent We consider a boolean disk coverage model which is the most
465 widely used sensor coverage model in the literature. Each sensor has a
466 constant sensing range $R_s$. All space points within a disk centered
467 at the sensor with the radius of the sensing range is said to be
468 covered by this sensor. We also assume that the communication range is
469 at least twice of the sensing range. In fact, Zhang and
470 Zhou~\cite{Zhang05} prove that if the transmission range fulfills the
471 previous hypothesis, a complete coverage of a convex area implies
472 connectivity among the working nodes in the active mode.
473 %To calculate the coverage ratio for the area of interest, we can propose the following coverage model which is called Wireless Sensor Node Area Coverage Model to ensure that all the area within each node sensing range are covered. We can calculate the positions of the points in the circle disc of the sensing range of wireless sensor node based on the Unit Circle in figure~\ref{fig:cluster1}:
478 %%\includegraphics[scale=0.25]{fig1.pdf}\\ %& \includegraphics[scale=0.10]{1.pdf} \\
479 %%(A) Figure 1 & (B) Figure 2
481 %\caption{Unit Circle in radians. }
482 %\label{fig:cluster1}
485 %By using the Unit Circle in figure~\ref{fig:cluster1},
486 %We choose to representEach wireless sensor node will be represented into a selected number of primary points by which we can know if the sensor node is covered or not.
487 % Figure ~\ref{fig:cluster2} shows the selected primary points that represents the area of the sensor node and according to the sensing range of the wireless sensor node.
489 \noindent Instead of working with area coverage, we consider for each
490 sensor a set of points called primary points. We also assume that the
491 sensing disk defined by a sensor is covered if all primary points of
492 this sensor are covered.
496 %%\includegraphics[scale=0.25]{fig2.pdf}\\ %& \includegraphics[scale=0.10]{1.pdf} \\
497 %%(A) Figure 1 & (B) Figure 2
499 %\caption{Wireless Sensor Node Area Coverage Model.}
500 %\label{fig:cluster2}
502 By knowing the position (point center: ($p_x,p_y$)) of a wireless
503 sensor node and its $R_s$, we calculate the primary points directly
504 based on the proposed model. We use these primary points (that can be
505 increased or decreased if necessary) as references to ensure that the
506 monitored region of interest is covered by the selected set of
507 sensors, instead of using all points in the area.
509 \noindent We can calculate the positions of the selected primary
510 points in the circle disk of the sensing range of a wireless sensor
511 node (see figure~\ref{fig2}) as follows:\\
512 $(p_x,p_y)$ = point center of wireless sensor node\\
514 $X_2=( p_x + R_s * (1), p_y + R_s * (0) )$\\
515 $X_3=( p_x + R_s * (-1), p_y + R_s * (0)) $\\
516 $X_4=( p_x + R_s * (0), p_y + R_s * (1) )$\\
517 $X_5=( p_x + R_s * (0), p_y + R_s * (-1 )) $\\
518 $X_6= ( p_x + R_s * (\frac{-\sqrt{2}}{2}), p_y + R_s * (0)) $\\
519 $X_7=( p_x + R_s * (\frac{\sqrt{2}}{2}), p_y + R_s * (0))$\\
520 $X_8=( p_x + R_s * (\frac{-\sqrt{2}}{2}), p_y + R_s * (\frac{-\sqrt{2}}{2})) $\\
521 $X_9=( p_x + R_s * (\frac{\sqrt{2}}{2}), p_y + R_s * (\frac{-\sqrt{2}}{2})) $\\
522 $X_{10}=( p_x + R_s * (\frac{-\sqrt{2}}{2}), p_y + R_s * (\frac{\sqrt{2}}{2})) $\\
523 $X_{11}=( p_x + R_s * (\frac{\sqrt{2}}{2}), p_y + R_s * (\frac{\sqrt{2}}{2})) $\\
524 $X_{12}=( p_x + R_s * (0), p_y + R_s * (\frac{\sqrt{2}}{2})) $\\
525 $X_{13}=( p_x + R_s * (0), p_y + R_s * (\frac{-\sqrt{2}}{2})) $.
529 % \begin{multicols}{6}
531 %\includegraphics[scale=0.10]{fig21.pdf}\\~ ~ ~(a)
532 %\includegraphics[scale=0.10]{fig22.pdf}\\~ ~ ~(b)
533 \includegraphics[scale=0.25]{principles13.eps}
534 %\includegraphics[scale=0.10]{fig25.pdf}\\~ ~ ~(d)
535 %\includegraphics[scale=0.10]{fig26.pdf}\\~ ~ ~(e)
536 %\includegraphics[scale=0.10]{fig27.pdf}\\~ ~ ~(f)
538 \caption{Wireless sensor node represented by 13 primary points}
542 \section{Coverage Problem Formulation}
544 %We can formulate our optimization problem as energy cost minimization by minimize the number of active sensor nodes and maximizing the coverage rate at the same time in each $A^k$ . This optimization problem can be formulated as follow: Since that we use a homogeneous wireless sensor network, we will assume that the cost of keeping a node awake is the same for all wireless sensor nodes in the network. We can define the decision parameter $X_j$ as in \eqref{eq11}:\\
547 %To satisfy the coverage requirement, the set of the principal points that will represent all the sensor nodes in the monitored region as $PSET= \lbrace P_1,\ldots ,P_p, \ldots , P_{N_P^k} \rbrace $, where $N_P^k = N_{sp} * N^k $ and according to the proposed model in figure ~\ref{fig:cluster2}. These points can be used by the wireless sensor node leader which will be chosen in each region in A to build a new parameter $\alpha_{jp}$ that represents the coverage possibility for each principal point $P_p$ of each wireless sensor node $s_j$ in $A^k$ as in \eqref{eq12}:\\
549 \noindent Our model is based on the model proposed by
550 \cite{pedraza2006} where the objective is to find a maximum number of
551 disjoint cover sets. To accomplish this goal, authors propose an
552 integer program which forces undercoverage and overcoverage of targets
553 to become minimal at the same time. They use binary variables
554 $x_{jl}$ to indicate if sensor $j$ belongs to cover set $l$. In our
555 model, we consider binary variables $X_{j}$ which determine the
556 activation of sensor $j$ in the sensing phase of the round. We also
557 consider primary points as targets. The set of primary points is
558 denoted by $P$ and the set of sensors by $J$.
560 \noindent For a primary point $p$, let $\alpha_{jp}$ denote the
561 indicator function of whether the point $p$ is covered, that is:
563 \alpha_{jp} = \left \{
565 1 & \mbox{if the primary point $p$ is covered} \\
566 & \mbox{by sensor node $j$}, \\
567 0 & \mbox{otherwise.}\\
571 The number of active sensors that cover the primary point $p$ is equal
572 to $\sum_{j \in J} \alpha_{jp} * X_{j}$ where:
576 1& \mbox{if sensor $j$ is active,} \\
577 0 & \mbox{otherwise.}\\
581 We define the Overcoverage variable $\Theta_{p}$ as:
583 \Theta_{p} = \left \{
585 0 & \mbox{if point $p$ is not covered,}\\
586 \left( \sum_{j \in J} \alpha_{jp} * X_{j} \right)- 1 & \mbox{otherwise.}\\
590 \noindent More precisely, $\Theta_{p}$ represents the number of active
591 sensor nodes minus one that cover the primary point $p$.\\
592 The Undercoverage variable $U_{p}$ of the primary point $p$ is defined
597 1 &\mbox{if point $p$ is not covered,} \\
598 0 & \mbox{otherwise.}\\
603 \noindent Our coverage optimization problem can then be formulated as follows\\
604 \begin{equation} \label{eq:ip2r}
607 \min \sum_{p \in P} (w_{\theta} \Theta_{p} + w_{U} U_{p})&\\
608 \textrm{subject to :}&\\
609 \sum_{j \in J} \alpha_{jp} X_{j} - \Theta_{p}+ U_{p} =1, &\forall p \in P\\
611 %\sum_{t \in T} X_{j,t} \leq \frac{RE_j}{e_t} &\forall j \in J \\
613 \Theta_{p}\in \mathbb{N} , &\forall p \in P\\
614 U_{p} \in \{0,1\}, &\forall p \in P \\
615 X_{j} \in \{0,1\}, &\forall j \in J
620 \item $X_{j}$ : indicates whether or not the sensor $j$ is actively
621 sensing in the round (1 if yes and 0 if not);
622 \item $\Theta_{p}$ : {\it overcoverage}, the number of sensors minus
623 one that are covering the primary point $p$;
624 \item $U_{p}$ : {\it undercoverage}, indicates whether or not point
625 $p$ is being covered (1 if not covered and 0 if covered).
628 The first group of constraints indicates that some primary point $p$
629 should be covered by at least one sensor and, if it is not always the
630 case, overcoverage and undercoverage variables help balance the
631 restriction equation by taking positive values. There are two main
632 objectives. First we limit overcoverage of primary points in order to
633 activate a minimum number of sensors. Second we prevent that parts of
634 the subregion are not monitored by minimizing undercoverage. The
635 weights $w_\theta$ and $w_U$ must be properly chosen so as to
636 guarantee that the maximum number of points are covered during each
639 %In equation \eqref{eq15}, there are two main objectives: the first one using the Overcoverage parameter to minimize the number of active sensor nodes in the produced final solution vector $X$ which leads to improve the life time of wireless sensor network. The second goal by using the Undercoverage parameter to maximize the coverage in the region by means of covering each primary point in $SSET^k$.The two objectives are achieved at the same time. The constraint which represented in equation \eqref{eq16} refer to the coverage function for each primary point $P_p$ in $SSET^k$ , where each $P_p$ should be covered by
640 %at least one sensor node in $A^k$. The objective function in \eqref{eq15} involving two main objectives to be optimized simultaneously, where optimal decisions need to be taken in the presence of trade-offs between the two conflicting main objectives in \eqref{eq15} and this refer to that our coverage optimization problem is a multi-objective optimization problem and we can use the BPSO to solve it. The concept of Overcoverage and Undercoverage inspired from ~\cite{Fernan12} but we use it with our model as stated in subsection \ref{Sensing Coverage Model} with some modification to be applied later by BPSO.
641 %\subsection{Notations and assumptions}
644 %\item $m$ : the number of targets
645 %\item $n$ : the number of sensors
646 %\item $K$ : maximal number of cover sets
647 %\item $i$ : index of target ($i=1..m$)
648 %\item $j$ : index of sensor ($j=1..n$)
649 %\item $k$ : index of cover set ($k=1..K$)
650 %\item $T_0$ : initial set of targets
651 %\item $S_0$ : initial set of sensors
652 %\item $T $ : set of targets which are not covered by at least one cover set
653 %\item $S$ : set of available sensors
654 %\item $S_0(i)$ : set of sensors which cover the target $i$
655 %\item $T_0(j)$ : set of targets covered by sensor $j$
656 %\item $C_k$ : cover set of index $k$
657 %\item $T(C_k)$ : set of targets covered by the cover set $k$
658 %\item $NS(i)$ : set of available sensors which cover the target $i$
659 %\item $NC(i)$ : set of cover sets which do not cover the target $i$
660 %\item $|.|$ : cardinality of the set
664 \section{Simulation Results}
667 In this section, we conducted a series of simulations to evaluate the
668 efficiency and relevance of our approach, using the discrete event
669 simulator OMNeT++ \cite{varga}. We performed simulations for five
670 different densities varying from 50 to 250~nodes. Experimental results
671 were obtained from randomly generated networks in which nodes are
672 deployed over a $(50 \times 25)~m^2 $ sensing field.
673 More precisely, the deployment is controlled at a coarse scale in
674 order to ensure that the deployed nodes can fully cover the sensing
675 field with the given sensing range.
676 10~simulation runs are performed with
677 different network topologies for each node density. The results
678 presented hereafter are the average of these 10 runs. A simulation
679 ends when all the nodes are dead or the sensor network becomes
680 disconnected (some nodes may not be able to sent to a base station an
683 Our proposed coverage protocol uses the radio energy dissipation model
684 defined by~\cite{HeinzelmanCB02} as energy consumption model for each
685 wireless sensor node when transmitting or receiving packets. The
686 energy of each node in a network is initialized randomly within the
687 range 24-60~joules, and each sensor node will consume 0.2 watts during
688 the sensing period which will have a duration of 60 seconds. Thus, an
689 active node will consume 12~joules during sensing phase, while a
690 sleeping node will use 0.002 joules. Each sensor node will not
691 participate in the next round if its remaining energy is less than 12
692 joules. In all experiments the parameters are set as follows:
693 $R_s=5m$, $w_{\Theta}=1$, and $w_{U}=|P^2|$.
695 We evaluate the efficiency of our approach using some performance
696 metrics such as: coverage ratio, number of active nodes ratio, energy
697 saving ratio, energy consumption, network lifetime, execution time,
698 and number of stopped simulation runs. Our approach called Strategy~2
699 (with Two Leaders) works with two subregions, each one having a size
700 of $(25 \times 25)~m^2$. Our strategy will be compared with two other
701 approaches. The first one, called Strategy~1 (with One Leader), works
702 as Strategy~2, but considers only one region of $(50 \times 25)$ $m^2$
703 with only one leader. The other approach, called Simple Heuristic,
704 consists in dividing uniformly the region into squares of $(5 \times
705 5)~m^2$. During the decision phase, in each square, a sensor is
706 randomly chosen, it will remain turned on for the coming sensing
709 \subsection{The impact of the Number of Rounds on Coverage Ratio}
711 In this experiment, the coverage ratio measures how much the area of a
712 sensor field is covered. In our case, the coverage ratio is regarded
713 as the number of primary points covered among the set of all primary
714 points within the field. Figure~\ref{fig3} shows the impact of the
715 number of rounds on the average coverage ratio for 150 deployed nodes
716 for the three approaches. It can be seen that the three approaches
717 give similar coverage ratios during the first rounds. From the
718 9th~round the coverage ratio decreases continuously with the simple
719 heuristic, while the two other strategies provide superior coverage to
720 $90\%$ for five more rounds. Coverage ratio decreases when the number
721 of rounds increases due to dead nodes. Although some nodes are dead,
722 thanks to strategy~1 or~2, other nodes are preserved to ensure the
723 coverage. Moreover, when we have a dense sensor network, it leads to
724 maintain the full coverage for larger number of rounds. Strategy~2 is
725 slightly more efficient that strategy 1, because strategy~2 subdivides
726 the region into 2~subregions and if one of the two subregions becomes
727 disconnected, coverage may be still ensured in the remaining
733 \includegraphics[scale=0.55]{TheCoverageRatio150.eps} %\\~ ~ ~(a)
734 \caption{The impact of the Number of Rounds on Coverage Ratio for 150 deployed nodes}
738 \subsection{The impact of the Number of Rounds on Active Sensors Ratio}
740 It is important to have as few active nodes as possible in each round,
741 in order to minimize the communication overhead and maximize the
742 network lifetime. This point is assessed through the Active Sensors
743 Ratio, which is defined as follows:
746 \mbox{ASR}(\%) = \frac{\mbox{Number of active sensors
747 during the current sensing phase}}{\mbox{Total number of sensors in the network
748 for the region}} \times 100.
750 Figure~\ref{fig4} shows the average active nodes ratio versus rounds
751 for 150 deployed nodes.
755 \includegraphics[scale=0.55]{TheActiveSensorRatio150.eps} %\\~ ~ ~(a)
756 \caption{The impact of the Number of Rounds on Active Sensors Ratio for 150 deployed nodes }
760 The results presented in figure~\ref{fig4} show the superiority of
761 both proposed strategies, the Strategy with Two Leaders and the one
762 with a single Leader, in comparison with the Simple Heuristic. The
763 Strategy with One Leader uses less active nodes than the Strategy with
764 Two Leaders until the last rounds, because it uses central control on
765 the whole sensing field. The advantage of the Strategy~2 approach is
766 that even if a network is disconnected in one subregion, the other one
767 usually continues the optimization process, and this extends the
768 lifetime of the network.
770 \subsection{The impact of the Number of Rounds on Energy Saving Ratio}
772 In this experiment, we consider a performance metric linked to energy.
773 This metric, called Energy Saving Ratio, is defined by:
776 \mbox{ESR}(\%) = \frac{\mbox{Number of alive sensors during this round}}
777 {\mbox{Total number of sensors in the network for the region}} \times 100.
779 The longer the ratio is high, the more redundant sensor nodes are
780 switched off, and consequently the longer the network may be alive.
781 Figure~\ref{fig5} shows the average Energy Saving Ratio versus rounds
782 for all three approaches and for 150 deployed nodes.
786 % \begin{multicols}{6}
788 \includegraphics[scale=0.55]{TheEnergySavingRatio150.eps} %\\~ ~ ~(a)
789 \caption{The impact of the Number of Rounds on Energy Saving Ratio for 150 deployed nodes}
793 The simulation results show that our strategies allow to efficiently
794 save energy by turning off some sensors during the sensing phase. As
795 expected, the Strategy with One Leader is usually slightly better than
796 the second strategy, because the global optimization permit to turn
797 off more sensors. Indeed, when there are two subregions more nodes
798 remain awake near the border shared by them. Note that again as the
799 number of rounds increases the two leader strategy becomes the most
800 performing, since its takes longer to have the two subregion networks
801 simultaneously disconnected.
803 \subsection{The Number of Stopped Simulation Runs}
805 We will now study the number of simulation which stopped due to
806 network disconnection, per round for each of the three approaches.
807 Figure~\ref{fig6} illustrates the average number of stopped simulation
808 runs per round for 150 deployed nodes. It can be observed that the
809 heuristic is the approach which stops the earlier because the nodes
810 are chosen randomly. Among the two proposed strategies, the
811 centralized one first exhibits network disconnection. Thus, as
812 explained previously, in case of the strategy with several subregions
813 the optimization effectively continues as long as a network in a
814 subregion is still connected. This longer partial coverage
815 optimization participates in extending the lifetime.
819 \includegraphics[scale=0.55]{TheNumberofStoppedSimulationRuns150.eps}
820 \caption{The Number of Stopped Simulation Runs against Rounds for 150 deployed nodes }
824 \subsection{The Energy Consumption}
826 In this experiment, we study the effect of the multi-hop communication
827 protocol on the performance of the Strategy with Two Leaders and
828 compare it with the other two approaches. The average energy
829 consumption resulting from wireless communications is calculated
830 considering the energy spent by all the nodes when transmitting and
831 receiving packets during the network lifetime. This average value,
832 which is obtained for 10~simulation runs, is then divided by the
833 average number of rounds to define a metric allowing a fair comparison
834 between networks having different densities.
836 Figure~\ref{fig7} illustrates the Energy Consumption for the different
837 network sizes and the three approaches. The results show that the
838 Strategy with Two Leaders is the most competitive from energy
839 consumption point of view. A centralized method, like the Strategy
840 with One Leader, has a high energy consumption due to the many
841 communications. In fact, a distributed method greatly reduces the
842 number of communications thanks to the partitioning of the initial
843 network in several independent subnetworks. Let us notice that even if
844 a centralized method consumes far more energy than the simple
845 heuristic, since the energy cost of communications during a round is a
846 small part of the energy spent in the sensing phase, the
847 communications have a small impact on the lifetime.
851 \includegraphics[scale=0.55]{TheEnergyConsumption.eps}
852 \caption{The Energy Consumption }
856 \subsection{The impact of Number of Sensors on Execution Time}
858 A sensor node has limited energy resources and computing power,
859 therefore it is important that the proposed algorithm has the shortest
860 possible execution time. The energy of a sensor node must be mainly
861 used for the sensing phase, not for the pre-sensing ones.
862 Table~\ref{table1} gives the average execution times in seconds
863 on a laptop of the decision phase (solving of the optimization problem)
864 during one round. They are given for the different approaches and
865 various numbers of sensors. The lack of any optimization explains why
866 the heuristic has very low execution times. Conversely, the Strategy
867 with One Leader which requires to solve an optimization problem
868 considering all the nodes presents redhibitory execution times.
869 Moreover, increasing of 50~nodes the network size multiplies the time
870 by almost a factor of 10. The Strategy with Two Leaders has more
871 suitable times. We think that in distributed fashion the solving of
872 the optimization problem in a subregion can be tackled by sensor
873 nodes. Overall, to be able deal with very large networks a
874 distributed method is clearly required.
877 \caption{The Execution Time(s) vs The Number of Sensors}
881 % used for centering table
882 \begin{tabular}{|c|c|c|c|}
883 % centered columns (4 columns)
885 %inserts double horizontal lines
886 Sensors Number & Strategy~1 & Strategy~2 & Simple Heuristic \\ [0.5ex]
887 & (with Two Leaders) & (with One Leader) & \\ [0.5ex]
888 %Case & Strategy (with Two Leaders) & Strategy (with One Leader) & Simple Heuristic \\ [0.5ex]
892 % inserts single horizontal line
893 50 & 0.097 & 0.189 & 0.001 \\
894 % inserting body of the table
896 100 & 0.419 & 1.972 & 0.0032 \\
898 150 & 1.295 & 13.098 & 0.0032 \\
900 200 & 4.54 & 169.469 & 0.0046 \\
902 250 & 12.252 & 1581.163 & 0.0056 \\
903 % [1ex] adds vertical space
908 % is used to refer this table in the text
911 \subsection{The Network Lifetime}
913 Finally, we have defined the network lifetime as the time until all
914 nodes have been drained of their energy or each sensor network
915 monitoring an area becomes disconnected. In figure~\ref{fig8}, the
916 network lifetime for different network sizes and for both Strategy
917 with Two Leaders and the Simple Heuristic is illustrated.
918 We do not consider anymore the centralized Strategy with One
919 Leader, because, as shown above, this strategy results in execution
920 times that quickly become unsuitable for a sensor network.
924 % \begin{multicols}{6}
926 \includegraphics[scale=0.5]{TheNetworkLifetime.eps} %\\~ ~ ~(a)
927 \caption{The Network Lifetime }
931 As highlighted by figure~\ref{fig8}, the network lifetime obviously
932 increases when the size of the network increase, with our approach
933 that leads to the larger lifetime improvement. By choosing for each
934 round the well suited nodes to cover the region of interest and by
935 letting the other ones sleep in order to be used later in next rounds,
936 our strategy efficiently prolongs the lifetime. Comparison shows that
937 the larger the sensor number is, the more our strategies outperform
938 the Simple Heuristic. Strategy~2, which uses two leaders, is the best
939 one because it is robust to network disconnection in one subregion. It
940 also means that distributing the algorithm in each node and
941 subdividing the sensing field into many subregions, which are managed
942 independently and simultaneously, is the most relevant way to maximize
943 the lifetime of a network.
945 \section{Conclusions and Future Works}
946 \label{sec:conclusion}
948 In this paper, we have addressed the problem of coverage and lifetime
949 optimization in wireless sensor networks. This is a key issue as
950 sensor nodes have limited resources in terms of memory, energy and
951 computational power. To cope with this problem, the field of sensing
952 is divided into smaller subregions using the concept of
953 divide-and-conquer method, and then a multi-rounds coverage protocol
954 will optimize coverage and lifetime performances in each subregion.
955 The proposed protocol combines two efficient techniques: network
956 Leader Election and sensor activity scheduling, where the challenges
957 include how to select the most efficient leader in each subregion and
958 the best representative active nodes that will optimize the lifetime
959 while taking the responsibility of covering the corresponding
960 subregion. The network lifetime in each subregion is divided into
961 rounds, each round consists of four phases: (i) Information Exchange,
962 (ii) Leader Election, (iii) an optimization-based Decision in order to
963 select the nodes remaining active for the last phase, and (iv)
964 Sensing. The simulations results show the relevance of the proposed
965 protocol in terms of lifetime, coverage ratio, active sensors Ratio,
966 energy saving, energy consumption, execution time, and the number of
967 stopped simulation runs due to network disconnection. Indeed, when
968 dealing with large and dense wireless sensor networks, a distributed
969 approach like the one we propose allows to reduce the difficulty of a
970 single global optimization problem by partitioning it in many smaller
971 problems, one per subregion, that can be solved more easily.
973 In future, we plan to study and propose a coverage protocol which
974 computes all active sensor schedules in a single round, using
975 optimization methods such as swarms optimization or evolutionary
976 algorithms. This single round will still consists of 4 phases, but the
977 decision phase will compute the schedules for several sensing phases
978 which aggregated together define a kind of meta-sensing phase.
979 The computation of all cover sets in one round is far more
980 difficult, but will reduce the communication overhead.
982 % use section* for acknowledgement
983 %\section*{Acknowledgment}
985 \bibliographystyle{IEEEtran}
986 \bibliography{bare_conf}