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44 \journal{Ad Hoc Networks}
50 %% Title, authors and addresses
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70 \title{Multiround Distributed Lifetime Coverage Optimization Protocol in Wireless Sensor Networks}
72 %% use optional labels to link authors explicitly to addresses:
73 %% \author[label1,label2]{}
76 %\author{Ali Kadhum Idrees, Karine Deschinkel, \\
77 %Michel Salomon, and Rapha\"el Couturier}
79 %\thanks{are members in the AND team - DISC department - FEMTO-ST Institute, University of Franche-Comt\'e, Belfort, France.
80 % e-mail: ali.idness@edu.univ-fcomte.fr, $\lbrace$karine.deschinkel, michel.salomon, raphael.couturier$\rbrace$@univ-fcomte.fr.}% <-this % stops a space
81 %\thanks{}% <-this % stops a space
83 %\address{FEMTO-ST Institute, University of Franche-Comt\'e, Belfort, France. \\
84 %e-mail: ali.idness@edu.univ-fcomte.fr, \\
85 %$\lbrace$karine.deschinkel, michel.salomon, raphael.couturier$\rbrace$@univ-fcomte.fr.}
88 \author{Ali Kadhum Idrees$^{a,b}$, Karine Deschinkel$^{a}$, \\
89 Michel Salomon$^{a}$ and Rapha\"el Couturier $^{a}$ \\
90 $^{a}${\em{FEMTO-ST Institute, UMR 6174 CNRS, \\
91 University Bourgogne Franche-Comt\'e, Belfort, France}} \\
92 $^{b}${\em{Department of Computer Science, University of Babylon, Babylon, Iraq}}
97 %One of the fundamental challenges in Wireless Sensor Networks (WSNs)
98 %is the coverage preservation and the extension of the network lifetime
99 %continuously and effectively when monitoring a certain area (or
100 %region) of interest.
101 Coverage and lifetime are two paramount problems in Wireless Sensor Networks
102 (WSNs). In this paper, a method called Multiround Distributed Lifetime Coverage
103 Optimization protocol (MuDiLCO) is proposed to maintain the coverage and to
104 improve the lifetime in wireless sensor networks. The area of interest is first
105 divided into subregions and then the MuDiLCO protocol is distributed on the
106 sensor nodes in each subregion. The proposed MuDiLCO protocol works in periods
107 during which sets of sensor nodes are scheduled to remain active for a number of
108 rounds during the sensing phase, to ensure coverage so as to maximize the
109 lifetime of WSN. \textcolor{green}{The decision process is carried out by a leader node, which
110 solves an optimization problem to produce the best representative sets to be used
111 during the rounds of the sensing phase. The optimization problem formulated as an integer program is solved either to optimality through a branch-and-Bound method or to near-optimality using a genetic algorithm-based heuristic. }
112 %The decision process is carried out by a leader node, which
113 %solves an integer program to produce the best representative sets to be used
114 %during the rounds of the sensing phase.
115 %\textcolor{red}{The integer program is solved by either GLPK solver or Genetic Algorithm (GA)}.
116 Compared with some existing protocols,
117 simulation results based on multiple criteria (energy consumption, coverage
118 ratio, and so on) show that the proposed protocol can prolong efficiently the
119 network lifetime and improve the coverage performance.
124 Wireless Sensor Networks, Area Coverage, Network Lifetime,
125 Optimization, Scheduling, Distributed Computation.
131 \section{Introduction}
133 \indent The fast developments of low-cost sensor devices and wireless
134 communications have allowed the emergence of WSNs. A WSN includes a large number
135 of small, limited-power sensors that can sense, process, and transmit data over
136 a wireless communication. They communicate with each other by using multi-hop
137 wireless communications and cooperate together to monitor the area of interest,
138 so that each measured data can be reported to a monitoring center called sink
139 for further analysis~\cite{Sudip03}. There are several fields of application
140 covering a wide spectrum for a WSN, including health, home, environmental,
141 military, and industrial applications~\cite{Akyildiz02}.
143 On the one hand sensor nodes run on batteries with limited capacities, and it is
144 often costly or simply impossible to replace and/or recharge batteries,
145 especially in remote and hostile environments. Obviously, to achieve a long life
146 of the network it is important to conserve battery power. Therefore, lifetime
147 optimization is one of the most critical issues in wireless sensor networks. On
148 the other hand we must guarantee coverage over the area of interest. To fulfill
149 these two objectives, the main idea is to take advantage of overlapping sensing
150 regions to turn-off redundant sensor nodes and thus save energy. In this paper,
151 we concentrate on the area coverage problem, with the objective of maximizing
152 the network lifetime by using an optimized multiround scheduling.
154 % One of the major scientific research challenges in WSNs, which are addressed by a large number of literature during the last few years is to design energy efficient approaches for coverage and connectivity in WSNs~\cite{conti2014mobile}. The coverage problem is one of the
155 %fundamental challenges in WSNs~\cite{Nayak04} that consists in monitoring efficiently and continuously
156 %the area of interest. The limited energy of sensors represents the main challenge in the WSNs
157 %design~\cite{Sudip03}, where it is difficult to replace and/or recharge their batteries because the the area of interest nature (such as hostile environments) and the cost. So, it is necessary that a WSN
158 %deployed with high density because spatial redundancy can then be exploited to increase the lifetime of the network. However, turn on all the sensor nodes, which monitor the same region at the same time
159 %leads to decrease the lifetime of the network. To extend the lifetime of the network, the main idea is to take advantage of the overlapping sensing regions of some sensor nodes to save energy by turning off
160 %some of them during the sensing phase~\cite{Misra05}. WSNs require energy-efficient solutions to improve the network lifetime that is constrained by the limited power of each sensor node ~\cite{Akyildiz02}.
162 %In this paper, we concentrate on the area coverage problem, with the objective
163 %of maximizing the network lifetime by using an optimized multirounds scheduling.
164 %The area of interest is divided into subregions.
166 % Each period includes four phases starts with a discovery phase to exchange information among the sensors of the subregion, in order to choose in a suitable manner a sensor node as leader to carry out a coverage strategy. This coverage strategy involves the solving of an integer program by the leader, to optimize the coverage and the lifetime in the subregion by producing a sets of sensor nodes in order to take the mission of coverage preservation during several rounds in the sensing phase. In fact, the nodes in a subregion can be seen as a cluster where each node sends sensing data to the cluster head or the sink node. Furthermore, the activities in a subregion/cluster can continue even if another cluster stops due to too many node failures.
168 The remainder of the paper is organized as follows. The next section
170 reviews the related works in the field. Section~\ref{pd} is devoted to the
171 description of MuDiLCO protocol. Section~\ref{exp} shows the simulation results
172 obtained using the discrete event simulator OMNeT++ \cite{varga}. They fully
173 demonstrate the usefulness of the proposed approach. Finally, we give
174 concluding remarks and some suggestions for future works in
175 Section~\ref{sec:conclusion}.
178 %%RC : Related works good for a phd thesis but too long for a paper. Ali you need to learn to .... summarize :-)
179 \section{Related works} % Trop proche de l'etat de l'art de l'article de Zorbas ?
182 \indent This section is dedicated to the various approaches proposed in the
183 literature for the coverage lifetime maximization problem, where the objective
184 is to optimally schedule sensors' activities in order to extend network lifetime
185 in WSNs. Cardei and Wu \cite{cardei2006energy} provide a taxonomy for coverage
186 algorithms in WSNs according to several design choices:
188 \item Sensors scheduling algorithm implementation, i.e. centralized or
189 distributed/localized algorithms.
190 \item The objective of sensor coverage, i.e. to maximize the network lifetime or
191 to minimize the number of active sensors during a sensing round.
192 \item The homogeneous or heterogeneous nature of the nodes, in terms of sensing
193 or communication capabilities.
194 \item The node deployment method, which may be random or deterministic.
195 \item Additional requirements for energy-efficient and connected coverage.
198 The choice of non-disjoint or disjoint cover sets (sensors participate or not in
199 many cover sets) can be added to the above list.
200 % The independency in the cover set (i.e. whether the cover sets are disjoint or non-disjoint) \cite{zorbas2010solving} is another design choice that can be added to the above list.
202 \subsection{Centralized approaches}
204 The major approach is to divide/organize the sensors into a suitable number of
205 cover sets where each set completely covers an interest region and to activate
206 these cover sets successively. The centralized algorithms always provide nearly
207 or close to optimal solution since the algorithm has global view of the whole
208 network. Note that centralized algorithms have the advantage of requiring very
209 low processing power from the sensor nodes, which usually have limited
210 processing capabilities. The main drawback of this kind of approach is its
211 higher cost in communications, since the node that will make the decision needs
212 information from all the sensor nodes. \textcolor{green} {Exact or heuristics approaches are designed to provide cover sets.
213 %(Moreover, centralized approaches usually
214 %suffer from the scalability problem, making them less competitive as the network
216 Contrary to exact methods, heuristic methods can handle very large and centralized problems. They are proposed to reduce computational overhead such as energy consumption, delay and generally increase in
217 the network lifetime. }
219 The first algorithms proposed in the literature consider that the cover sets are
220 disjoint: a sensor node appears in exactly one of the generated cover
221 sets~\cite{abrams2004set,cardei2005improving,Slijepcevic01powerefficient}. In
222 the case of non-disjoint algorithms \cite{pujari2011high}, sensors may
223 participate in more than one cover set. In some cases, this may prolong the
224 lifetime of the network in comparison to the disjoint cover set algorithms, but
225 designing algorithms for non-disjoint cover sets generally induces a higher
226 order of complexity. Moreover, in case of a sensor's failure, non-disjoint
227 scheduling policies are less resilient and reliable because a sensor may be
228 involved in more than one cover sets.
229 %For instance, the proposed work in ~\cite{cardei2005energy, berman04}
231 In~\cite{yang2014maximum}, the authors have considered a linear programming
232 approach to select the minimum number of working sensor nodes, in order to
233 preserve a maximum coverage and to extend lifetime of the network. Cheng et
234 al.~\cite{cheng2014energy} have defined a heuristic algorithm called Cover Sets
235 Balance (CSB), which chooses a set of active nodes using the tuple (data
236 coverage range, residual energy). Then, they have introduced a new Correlated
237 Node Set Computing (CNSC) algorithm to find the correlated node set for a given
238 node. After that, they proposed a High Residual Energy First (HREF) node
239 selection algorithm to minimize the number of active nodes so as to prolong the
240 network lifetime. Various centralized methods based on column generation
241 approaches have also been
242 proposed~\cite{gentili2013,castano2013column,rossi2012exact,deschinkel2012column}.
243 \textcolor{green}{In~\cite{gentili2013}, authors highlight the trade-off between the network lifetime and the coverage percentage. They show that network lifetime can be hugely improved by decreasing the coverage ratio. }
245 \subsection{Distributed approaches}
246 %{\bf Distributed approaches}
247 In distributed and localized coverage algorithms, the required computation to
248 schedule the activity of sensor nodes will be done by the cooperation among
249 neighboring nodes. These algorithms may require more computation power for the
250 processing by the cooperating sensor nodes, but they are more scalable for large
251 WSNs. Localized and distributed algorithms generally result in non-disjoint set
254 Many distributed algorithms have been developed to perform the scheduling so as
255 to preserve coverage, see for example
256 \cite{Gallais06,Tian02,Ye03,Zhang05,HeinzelmanCB02, yardibi2010distributed,
257 prasad2007distributed,Misra}. Distributed algorithms typically operate in
258 rounds for a predetermined duration. At the beginning of each round, a sensor
259 exchanges information with its neighbors and makes a decision to either remain
260 turned on or to go to sleep for the round. This decision is basically made on
261 simple greedy criteria like the largest uncovered area
262 \cite{Berman05efficientenergy} or maximum uncovered targets
263 \cite{lu2003coverage}. The Distributed Adaptive Sleep Scheduling Algorithm
264 (DASSA) \cite{yardibi2010distributed} does not require location information of
265 sensors while maintaining connectivity and satisfying a user defined coverage
266 target. In DASSA, nodes use the residual energy levels and feedback from the
267 sink for scheduling the activity of their neighbors. This feedback mechanism
268 reduces the randomness in scheduling that would otherwise occur due to the
269 absence of location information. In \cite{ChinhVu}, the author have designed a
270 novel distributed heuristic, called Distributed Energy-efficient Scheduling for
271 k-coverage (DESK), which ensures that the energy consumption among the sensors
272 is balanced and the lifetime maximized while the coverage requirement is
273 maintained. This heuristic works in rounds, requires only one-hop neighbor
274 information, and each sensor decides its status (active or sleep) based on the
275 perimeter coverage model from~\cite{Huang:2003:CPW:941350.941367}.
277 %Our Work, which is presented in~\cite{idrees2014coverage} proposed a coverage optimization protocol to improve the lifetime in
278 %heterogeneous energy wireless sensor networks.
279 %In this work, the coverage protocol distributed in each sensor node in the subregion but the optimization take place over the the whole subregion. We consider only distributing the coverage protocol over two subregions.
281 The works presented in \cite{Bang, Zhixin, Zhang} focus on coverage-aware,
282 distributed energy-efficient, and distributed clustering methods respectively,
283 which aim at extending the network lifetime, while the coverage is ensured.
284 More recently, Shibo et al. \cite{Shibo} have expressed the coverage problem as
285 a minimum weight submodular set cover problem and proposed a Distributed
286 Truncated Greedy Algorithm (DTGA) to solve it. They take advantage from both
287 temporal and spatial correlations between data sensed by different sensors, and
288 leverage prediction, to improve the lifetime. In \cite{xu2001geography}, Xu et
289 al. have described an algorithm, called Geographical Adaptive Fidelity (GAF),
290 which uses geographic location information to divide the area of interest into
291 fixed square grids. Within each grid, it keeps only one node staying awake to
292 take the responsibility of sensing and communication.
294 Some other approaches (outside the scope of our work) do not consider a
295 synchronized and predetermined time-slot where the sensors are active or not.
296 Indeed, each sensor maintains its own timer and its wake-up time is randomized
297 \cite{Ye03} or regulated \cite{cardei2005maximum} over time.
299 The MuDiLCO protocol (for Multiround Distributed Lifetime Coverage Optimization
300 protocol) presented in this paper is an extension of the approach introduced
301 in~\cite{idrees2014coverage}. In~\cite{idrees2014coverage}, the protocol is
302 deployed over only two subregions. Simulation results have shown that it was
303 more interesting to divide the area into several subregions, given the
304 computation complexity. Compared to our previous paper, in this one we study the
305 possibility of dividing the sensing phase into multiple rounds and we also add
306 an improved model of energy consumption to assess the efficiency of our
307 approach. In fact, in this paper we make a multiround optimization, while it was
308 a single round optimization in our previous work. \textcolor{green}{The idea is to take advantage of the pre-sensing phase
309 to plan the sensor's activity for several rounds instead of one, thus saving energy. In addition, as the optimization problem has become more complex, a GA-based heuristic is proposed to solve it}.
313 \subsection{Centralized Approaches}
314 %{\bf Centralized approaches}
315 The major approach is to divide/organize the sensors into a suitable number of
316 set covers where each set completely covers an interest region and to activate
317 these set covers successively. The centralized algorithms always provide nearly
318 or close to optimal solution since the algorithm has global view of the whole
319 network. Note that centralized algorithms have the advantage of requiring very
320 low processing power from the sensor nodes, which usually have limited
321 processing capabilities. The main drawback of this kind of approach is its
322 higher cost in communications, since the node that will take the decision needs
323 information from all the sensor nodes. Moreover, centralized approaches usually
324 suffer from the scalability problem, making them less competitive as the network
327 The first algorithms proposed in the literature consider that the cover sets are
328 disjoint: a sensor node appears in exactly one of the generated cover sets. For
329 instance, Slijepcevic and Potkonjak \cite{Slijepcevic01powerefficient} have
330 proposed an algorithm, which allocates sensor nodes in mutually independent sets
331 to monitor an area divided into several fields. Their algorithm builds a cover
332 set by including in priority the sensor nodes which cover critical fields, that
333 is to say fields that are covered by the smallest number of sensors. The time
334 complexity of their heuristic is $O(n^2)$ where $n$ is the number of sensors.
335 Abrams et al.~\cite{abrams2004set} have designed three approximation algorithms
336 for a variation of the set k-cover problem, where the objective is to partition
337 the sensors into covers such that the number of covers that include an area,
338 summed over all areas, is maximized. Their work builds upon previous work
339 in~\cite{Slijepcevic01powerefficient} and the generated cover sets do not
340 provide complete coverage of the monitoring zone.
342 In \cite{cardei2005improving}, the authors have proposed a method to efficiently
343 compute the maximum number of disjoint set covers such that each set can monitor
344 all targets. They first transform the problem into a maximum flow problem, which
345 is formulated as a mixed integer programming (MIP). Then their heuristic uses
346 the output of the MIP to compute disjoint set covers. Results show that this
347 heuristic provides a number of set covers slightly larger compared to
348 \cite{Slijepcevic01powerefficient}, but with a larger execution time due to the
349 complexity of the mixed integer programming resolution.
351 Zorbas et al. \cite{zorbas2010solving} presented a centralized greedy algorithm
352 for the efficient production of both node disjoint and non-disjoint cover sets.
353 Compared to algorithm's results of Slijepcevic and Potkonjak
354 \cite{Slijepcevic01powerefficient}, their heuristic produces more disjoint cover
355 sets with a slight growth rate in execution time. When producing non-disjoint
356 cover sets, both Static-CCF and Dynamic-CCF algorithms, where CCF means that
357 they use a cost function called Critical Control Factor, provide cover sets
358 offering longer network lifetime than those produced by \cite{cardei2005energy}.
359 Also, they require a smaller number of participating nodes in order to achieve
362 In the case of non-disjoint algorithms \cite{pujari2011high}, sensors may
363 participate in more than one cover set. In some cases, this may prolong the
364 lifetime of the network in comparison to the disjoint cover set algorithms, but
365 designing algorithms for non-disjoint cover sets generally induces a higher
366 order of complexity. Moreover, in case of a sensor's failure, non-disjoint
367 scheduling policies are less resilient and less reliable because a sensor may be
368 involved in more than one cover sets. For instance, Cardei et
369 al.~\cite{cardei2005energy} present a linear programming (LP) solution and a
370 greedy approach to extend the sensor network lifetime by organizing the sensors
371 into a maximal number of non-disjoint cover sets. Simulation results show that
372 by allowing sensors to participate in multiple sets, the network lifetime
373 increases compared with related work~\cite{cardei2005improving}.
374 In~\cite{berman04}, the authors have formulated the lifetime problem and
375 suggested another (LP) technique to solve this problem. A centralized solution
376 based on the Garg-K\"{o}nemann algorithm~\cite{garg98}, provably near the
377 optimal solution, is also proposed.
379 In~\cite{yang2014maximum}, the authors have proposed a linear programming
380 approach for selecting the minimum number of working sensor nodes, in order to
381 as to preserve a maximum coverage and extend lifetime of the network. Cheng et
382 al.~\cite{cheng2014energy} have defined a heuristic algorithm called Cover Sets
383 Balance (CSB), which choose a set of active nodes using the tuple (data coverage
384 range, residual energy). Then, they have introduced a new Correlated Node Set
385 Computing (CNSC) algorithm to find the correlated node set for a given node.
386 After that, they proposed a High Residual Energy First (HREF) node selection
387 algorithm to minimize the number of active nodes so as to prolong the network
388 lifetime. Various centralized methods based on column generation approaches have
389 also been proposed~\cite{castano2013column,rossi2012exact,deschinkel2012column}.
391 \subsection{Distributed approaches}
392 %{\bf Distributed approaches}
393 In distributed and localized coverage algorithms, the required computation to
394 schedule the activity of sensor nodes will be done by the cooperation among
395 neighboring nodes. These algorithms may require more computation power for the
396 processing by the cooperating sensor nodes, but they are more scalable for large
397 WSNs. Localized and distributed algorithms generally result in non-disjoint set
400 Many distributed algorithms have been developed to perform the scheduling so as
401 to preserve coverage, see for example
402 \cite{Gallais06,Tian02,Ye03,Zhang05,HeinzelmanCB02,yardibi2010distributed}.
403 Distributed algorithms typically operate in rounds for a predetermined
404 duration. At the beginning of each round, a sensor exchanges information with
405 its neighbors and makes a decision to either remain turned on or to go to sleep
406 for the round. This decision is basically made on simple greedy criteria like
407 the largest uncovered area \cite{Berman05efficientenergy} or maximum uncovered
408 targets \cite{lu2003coverage}. In \cite{Tian02}, the scheduling scheme is
409 divided into rounds, where each round has a self-scheduling phase followed by a
410 sensing phase. Each sensor broadcasts a message containing the node~ID and the
411 node location to its neighbors at the beginning of each round. A sensor
412 determines its status by a rule named off-duty eligible rule, which tells him to
413 turn off if its sensing area is covered by its neighbors. A back-off scheme is
414 introduced to let each sensor delay the decision process with a random period of
415 time, in order to avoid simultaneous conflicting decisions between nodes and
416 lack of coverage on any area. In \cite{prasad2007distributed} a model for
417 capturing the dependencies between different cover sets is defined and it
418 proposes localized heuristic based on this dependency. The algorithm consists of
419 two phases, an initial setup phase during which each sensor computes and
420 prioritizes the covers and a sensing phase during which each sensor first
421 decides its on/off status, and then remains on or off for the rest of the
424 The authors in \cite{yardibi2010distributed} have developed a Distributed
425 Adaptive Sleep Scheduling Algorithm (DASSA) for WSNs with partial coverage.
426 DASSA does not require location information of sensors while maintaining
427 connectivity and satisfying a user defined coverage target. In DASSA, nodes use
428 the residual energy levels and feedback from the sink for scheduling the
429 activity of their neighbors. This feedback mechanism reduces the randomness in
430 scheduling that would otherwise occur due to the absence of location
431 information. In \cite{ChinhVu}, the author have proposed a novel distributed
432 heuristic, called Distributed Energy-efficient Scheduling for k-coverage (DESK),
433 which ensures that the energy consumption among the sensors is balanced and the
434 lifetime maximized while the coverage requirement is maintained. This heuristic
435 works in rounds, requires only one-hop neighbor information, and each sensor
436 decides its status (active or sleep) based on the perimeter coverage model
437 proposed in \cite{Huang:2003:CPW:941350.941367}.
439 %Our Work, which is presented in~\cite{idrees2014coverage} proposed a coverage optimization protocol to improve the lifetime in
440 %heterogeneous energy wireless sensor networks.
441 %In this work, the coverage protocol distributed in each sensor node in the subregion but the optimization take place over the the whole subregion. We consider only distributing the coverage protocol over two subregions.
443 The works presented in \cite{Bang, Zhixin, Zhang} focus on coverage-aware,
444 distributed energy-efficient, and distributed clustering methods respectively,
445 which aim to extend the network lifetime, while the coverage is ensured. S.
446 Misra et al. \cite{Misra} have proposed a localized algorithm for coverage in
447 sensor networks. The algorithm conserve the energy while ensuring the network
448 coverage by activating the subset of sensors with the minimum overlap area. The
449 proposed method preserves the network connectivity by formation of the network
450 backbone. More recently, Shibo et al. \cite{Shibo} have expressed the coverage
451 problem as a minimum weight submodular set cover problem and proposed a
452 Distributed Truncated Greedy Algorithm (DTGA) to solve it. They take advantage
453 from both temporal and spatial correlations between data sensed by different
454 sensors, and leverage prediction, to improve the lifetime. In
455 \cite{xu2001geography}, Xu et al. have proposed an algorithm, called
456 Geographical Adaptive Fidelity (GAF), which uses geographic location information
457 to divide the area of interest into fixed square grids. Within each grid, it
458 keeps only one node staying awake to take the responsibility of sensing and
461 Some other approaches (outside the scope of our work) do not consider a
462 synchronized and predetermined period of time where the sensors are active or
463 not. Indeed, each sensor maintains its own timer and its wake-up time is
464 randomized \cite{Ye03} or regulated \cite{cardei2005maximum} over time.
466 The MuDiLCO protocol (for Multiround Distributed Lifetime Coverage Optimization
467 protocol) presented in this paper is an extension of the approach introduced
468 in~\cite{idrees2014coverage}. In~\cite{idrees2014coverage}, the protocol is
469 deployed over only two subregions. Simulation results have shown that it was
470 more interesting to divide the area into several subregions, given the
471 computation complexity. Compared to our previous paper, in this one we study the
472 possibility of dividing the sensing phase into multiple rounds and we also add
473 an improved model of energy consumption to assess the efficiency of our
480 %The main contributions of our MuDiLCO Protocol can be summarized as follows:
481 %(1) The high coverage ratio, (2) The reduced number of active nodes, (3) The distributed optimization over the subregions in the area of interest, (4) The distributed dynamic leader election at each round based on some priority factors that led to energy consumption balancing among the nodes in the same subregion, (5) The primary point coverage model to represent each sensor node in the network, (6) The activity scheduling based optimization on the subregion, which are based on the primary point coverage model to activate as less number as possible of sensor nodes for a multirounds to take the mission of the coverage in each subregion, (7) The very low energy consumption, (8) The higher network lifetime.
482 %\section{Preliminaries}
487 %\subsection{Network Lifetime}
488 %Various definitions exist for the lifetime of a sensor
489 %network~\cite{die09}. The main definitions proposed in the literature are
490 %related to the remaining energy of the nodes or to the coverage percentage.
491 %The lifetime of the network is mainly defined as the amount
492 %of time during which the network can satisfy its coverage objective (the
493 %amount of time that the network can cover a given percentage of its
494 %area or targets of interest). In this work, we assume that the network
495 %is alive until all nodes have been drained of their energy or the
496 %sensor network becomes disconnected, and we measure the coverage ratio
497 %during the WSN lifetime. Network connectivity is important because an
498 %active sensor node without connectivity towards a base station cannot
499 %transmit information on an event in the area that it monitors.
501 \section{MuDiLCO protocol description}
504 %Our work will concentrate on the area coverage by design
505 %and implementation of a strategy, which efficiently selects the active
506 %nodes that must maintain both sensing coverage and network
507 %connectivity and at the same time improve the lifetime of the wireless
508 %sensor network. But, requiring that all physical points of the
509 %considered region are covered may be too strict, especially where the
510 %sensor network is not dense. Our approach represents an area covered
511 %by a sensor as a set of primary points and tries to maximize the total
512 %number of primary points that are covered in each round, while
513 %minimizing overcoverage (points covered by multiple active sensors
516 %In this section, we introduce a Multiround Distributed Lifetime Coverage Optimization protocol, which is called MuDiLCO. It is distributed on each subregion in the area of interest. It is based on two efficient techniques: network
517 %leader election and sensor activity scheduling for coverage preservation and energy conservation continuously and efficiently to maximize the lifetime in the network.
518 %The main features of our MuDiLCO protocol:
519 %i)It divides the area of interest into subregions by using divide-and-conquer concept, ii)It requires only the information of the nodes within the subregion, iii) it divides the network lifetime into periods, which consists in round(s), iv)It based on the autonomous distributed decision by the nodes in the subregion to elect the Leader, v)It apply the activity scheduling based optimization on the subregion, vi) it achieves an energy consumption balancing among the nodes in the subregion by selecting different nodes as a leader during the network lifetime, vii) It uses the optimization to select the best representative non-disjoint sets of sensors in the subregion by optimize the coverage and the lifetime over the area of interest, viii)It uses our proposed primary point coverage model, which represent the sensing range of the sensor as a set of points, which are used by the our optimization algorithm, ix) It uses a simple energy model that takes communication, sensing and computation energy consumptions into account to evaluate the performance of our Protocol.
521 \subsection{Assumptions}
523 We consider a randomly and uniformly deployed network consisting of static
524 wireless sensors. The sensors are deployed in high density to ensure initially
525 a high coverage ratio of the interested area. We assume that all nodes are
526 homogeneous in terms of communication and processing capabilities, and
527 heterogeneous from the point of view of energy provision. Each sensor is
528 supposed to get information on its location either through hardware such as
529 embedded GPS or through location discovery algorithms.
531 To model a sensor node's coverage area, we consider the boolean disk coverage
532 model which is the most widely used sensor coverage model in the
533 literature. Thus, each sensor has a constant sensing range $R_s$ and all space
534 points within the disk centered at the sensor with the radius of the sensing
535 range is said to be covered by this sensor. We also assume that the
536 communication range satisfies $R_c \geq 2R_s$. In fact, Zhang and
537 Zhou~\cite{Zhang05} proved that if the transmission range fulfills the previous
538 hypothesis, a complete coverage of a convex area implies connectivity among the
541 %Instead of working with a continuous coverage area, we make it discrete by considering for each sensor a set of points called primary points. Consequently, we assume that the sensing disk defined by a sensor is covered if all of its primary points are covered. The choice of number and locations of primary points is the subject of another study not presented here.
544 \indent Instead of working with the coverage area, we consider for each sensor a set of points called primary points~\cite{idrees2014coverage}. We also assume that the sensing disk defined by a sensor is covered if all the primary points of this sensor are covered. By knowing the position (point center: ($p_x,p_y$)) of a wireless sensor node and it's sensing range $R_s$, we calculate the primary points directly based on the proposed model. We use these primary points (that can be increased or decreased if necessary) as references to ensure that the monitored region of interest is covered by the selected set of sensors, instead of using all the points in the area.
545 We can calculate the positions of the selected primary
546 points in the circle disk of the sensing range of a wireless sensor
547 node (see Figure~\ref{fig1}) as follows:\\
548 Assuming that the point center of a wireless sensor node is located at $(p_x,p_y)$, we can define up to 25 primary points $X_1$ to $X_{25}$.\\
549 %$(p_x,p_y)$ = point center of wireless sensor node\\
551 $X_2=( p_x + R_s * (1), p_y + R_s * (0) )$\\
552 $X_3=( p_x + R_s * (-1), p_y + R_s * (0)) $\\
553 $X_4=( p_x + R_s * (0), p_y + R_s * (1) )$\\
554 $X_5=( p_x + R_s * (0), p_y + R_s * (-1 )) $\\
555 $X_6= ( p_x + R_s * (\frac{-\sqrt{2}}{2}), p_y + R_s * (0)) $\\
556 $X_7=( p_x + R_s * (\frac{\sqrt{2}}{2}), p_y + R_s * (0))$\\
557 $X_8=( p_x + R_s * (\frac{-\sqrt{2}}{2}), p_y + R_s * (\frac{-\sqrt{2}}{2})) $\\
558 $X_9=( p_x + R_s * (\frac{\sqrt{2}}{2}), p_y + R_s * (\frac{-\sqrt{2}}{2})) $\\
559 $X_{10}=( p_x + R_s * (\frac{-\sqrt{2}}{2}), p_y + R_s * (\frac{\sqrt{2}}{2})) $\\
560 $X_{11}=( p_x + R_s * (\frac{\sqrt{2}}{2}), p_y + R_s * (\frac{\sqrt{2}}{2})) $\\
561 $X_{12}=( p_x + R_s * (0), p_y + R_s * (\frac{\sqrt{2}}{2})) $\\
562 $X_{13}=( p_x + R_s * (0), p_y + R_s * (\frac{-\sqrt{2}}{2})) $\\
563 $X_{14}=( p_x + R_s * (\frac{\sqrt{3}}{2}), p_y + R_s * (\frac{1}{2})) $\\
564 $X_{15}=( p_x + R_s * (\frac{-\sqrt{3}}{2}), p_y + R_s * (\frac{1}{2})) $\\
565 $X_{16}=( p_x + R_s * (\frac{\sqrt{3}}{2}), p_y + R_s * (\frac{- 1}{2})) $\\
566 $X_{17}=( p_x + R_s * (\frac{-\sqrt{3}}{2}), p_y + R_s * (\frac{- 1}{2})) $\\
567 $X_{18}=( p_x + R_s * (\frac{\sqrt{3}}{2}), p_y + R_s * (0) $\\
568 $X_{19}=( p_x + R_s * (\frac{-\sqrt{3}}{2}), p_y + R_s * (0) $\\
569 $X_{20}=( p_x + R_s * (0), p_y + R_s * (\frac{1}{2})) $\\
570 $X_{21}=( p_x + R_s * (0), p_y + R_s * (-\frac{1}{2})) $\\
571 $X_{22}=( p_x + R_s * (\frac{1}{2}), p_y + R_s * (\frac{\sqrt{3}}{2})) $\\
572 $X_{23}=( p_x + R_s * (\frac{- 1}{2}), p_y + R_s * (\frac{\sqrt{3}}{2})) $\\
573 $X_{24}=( p_x + R_s * (\frac{- 1}{2}), p_y + R_s * (\frac{-\sqrt{3}}{2})) $\\
574 $X_{25}=( p_x + R_s * (\frac{1}{2}), p_y + R_s * (\frac{-\sqrt{3}}{2})) $.
582 \includegraphics[scale=0.28]{fig21.pdf}\\~ (a)
583 \includegraphics[scale=0.28]{principles13.pdf}\\~(c)
585 \includegraphics[scale=0.28]{fig25.pdf}\\~(e)
586 \includegraphics[scale=0.28]{fig22.pdf}\\~(b)
588 \includegraphics[scale=0.28]{fig24.pdf}\\~(d)
589 \includegraphics[scale=0.28]{fig26.pdf}\\~(f)
591 \caption{Wireless Sensor Node represented by (a) 5, (b) 9, (c) 13, (d) 17, (e) 21 and (f) 25 primary points respectively}
600 %By knowing the position (point center: ($p_x,p_y$)) of a wireless
601 %sensor node and its $R_s$, we calculate the primary points directly
602 %based on the proposed model. We use these primary points (that can be
603 %increased or decreased if necessary) as references to ensure that the
604 %monitored region of interest is covered by the selected set of
605 %sensors, instead of using all the points in the area.
607 %The MuDiLCO protocol works in periods and executed at each sensor node in the network, each sensor node can still sense data while being in
608 %LISTENING mode. Thus, by entering the LISTENING mode at the beginning of each round,
609 %sensor nodes still executing sensing task while participating in the leader election and decision phases. More specifically, The MuDiLCO protocol algorithm works as follow:
610 %Initially, the sensor node check it's remaining energy in order to participate in the current round. Each sensor node determines it's position and it's subregion based Embedded GPS or Location Discovery Algorithm. After that, All the sensors collect position coordinates, current remaining energy, sensor node id, and the number of its one-hop live neighbors during the information exchange. It stores this information into a list $L$.
611 %The sensor node enter in listening mode waiting to receive ActiveSleep packet from the leader after the decision to apply multi-round activity scheduling during the sensing phase. Each sensor node will execute the Algorithm~1 to know who is the leader. After that, if the sensor node is leader, It will execute the integer program algorithm ( see section~\ref{cp}) to optimize the coverage and the lifetime in it's subregion. After the decision, the optimization approach will produce the cover sets of sensor nodes to take the mission of coverage during the sensing phase for $T$ rounds. The leader will send ActiveSleep packet to each sensor node in the subregion to inform him to it's schedule for $T$ rounds during the period of sensing, either Active or sleep until the starting of next period. Based on the decision, the leader as other nodes in subregion, either go to be active or go to be sleep based on it's schedule for $T$ rounds during current sensing phase. the other nodes in the same subregion will stay in listening mode waiting the ActiveSleep packet from the leader. After finishing the time period for sensing, which are includes $T$ rounds, all the sensor nodes in the same subregion will start new period by executing the MuDiLCO protocol and the lifetime in the subregion will continue until all the sensor nodes are died or the network becomes disconnected in the subregion.
613 \subsection{Background idea}
614 %%RC : we need to clarify the difference between round and period. Currently it seems to be the same (for me at least).
615 The area of interest can be divided using the divide-and-conquer strategy into
616 smaller areas, called subregions, and then our MuDiLCO protocol will be
617 implemented in each subregion in a distributed way.
619 As can be seen in Figure~\ref{fig2}, our protocol works in periods fashion,
620 where each is divided into 4 phases: Information~Exchange, Leader~Election,
621 Decision, and Sensing. Each sensing phase may be itself divided into $T$ rounds
622 \textcolor{green} {of equal duration} and for each round a set of sensors (a cover set) is responsible for the sensing
623 task. In this way a multiround optimization process is performed during each
624 period after Information~Exchange and Leader~Election phases, in order to
625 produce $T$ cover sets that will take the mission of sensing for $T$ rounds.
627 \centering \includegraphics[width=100mm]{Modelgeneral.pdf} % 70mm
628 \caption{The MuDiLCO protocol scheme executed on each node}
632 %Each period is divided into 4 phases: Information Exchange,
633 %Leader Election, Decision, and Sensing. Each sensing phase may be itself divided into $T$ rounds.
634 % set cover responsible for the sensing task.
635 %For each round a set of sensors (said a cover set) is responsible for the sensing task.
637 This protocol minimizes the impact of unexpected node failure (not due to batteries
638 running out of energy), because it works in periods.
639 %This protocol is reliable against an unexpected node failure, because it works in periods.
640 %%RC : why? I am not convinced
641 On the one hand, if a node failure is detected before making the
642 decision, the node will not participate to this phase, and, on the other hand,
643 if the node failure occurs after the decision, the sensing task of the network
644 will be temporarily affected: only during the period of sensing until a new
645 period starts. \textcolor{green}{The duration of the rounds are predefined parameters. Round duration should be long enough to hide the system control overhead and short enough to minimize the negative effects in case of node failure.}
647 %%RC so if there are at least one failure per period, the coverage is bad...
648 %%MS if we want to be reliable against many node failures we need to have an
651 The energy consumption and some other constraints can easily be taken into
652 account, since the sensors can update and then exchange their information
653 (including their residual energy) at the beginning of each period. However, the
654 pre-sensing phases (Information Exchange, Leader Election, and Decision) are
655 energy consuming for some nodes, even when they do not join the network to
658 %%%%%%%%%%%%%%%%%parler optimisation%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
660 We define two types of packets that will be used by the proposed protocol:
661 \begin{enumerate}[(a)]
662 \item INFO packet: such a packet will be sent by each sensor node to all the
663 nodes inside a subregion for information exchange.
664 \item Active-Sleep packet: sent by the leader to all the nodes inside a
665 subregion to inform them to remain Active or to go Sleep during the sensing
669 There are five status for each sensor node in the network:
670 \begin{enumerate}[(a)]
671 \item LISTENING: sensor node is waiting for a decision (to be active or not);
672 \item COMPUTATION: sensor node has been elected as leader and applies the
673 optimization process;
674 \item ACTIVE: sensor node is taking part in the monitoring of the area;
675 \item SLEEP: sensor node is turned off to save energy;
676 \item COMMUNICATION: sensor node is transmitting or receiving packet.
679 Below, we describe each phase in more details.
681 \subsection{Information Exchange Phase}
683 Each sensor node $j$ sends its position, remaining energy $RE_j$, and the number
684 of neighbors $NBR_j$ to all wireless sensor nodes in its subregion by using an
685 INFO packet (containing information on position coordinates, current remaining
686 energy, sensor node ID, number of its one-hop live neighbors) and then waits for
687 packets sent by other nodes. After that, each node will have information about
688 all the sensor nodes in the subregion. In our model, the remaining energy
689 corresponds to the time that a sensor can live in the active mode.
691 %\subsection{\textbf Working Phase:}
693 %The working phase works in rounding fashion. Each round include 3 steps described as follow :
695 \subsection{Leader Election phase}
697 This step consists in choosing the Wireless Sensor Node Leader (WSNL), which
698 will be responsible for executing the coverage algorithm. Each subregion in the
699 area of interest will select its own WSNL independently for each period. All
700 the sensor nodes cooperate to elect a WSNL. The nodes in the same subregion
701 will select the leader based on the received information from all other nodes
702 in the same subregion. The selection criteria are, in order of importance:
703 larger number of neighbors, larger remaining energy, and then in case of
704 equality, larger index. Observations on previous simulations suggest to use the
705 number of one-hop neighbors as the primary criterion to reduce energy
706 consumption due to the communications.
708 %the more priority selection factor is the number of $1-hop$ neighbors, $NBR j$, which can minimize the energy consumption during the communication Significantly.
709 %The pseudo-code for leader election phase is provided in Algorithm~1.
711 %Where $E_{th}$ is the minimum energy needed to stay active during the sensing phase. As shown in Algorithm~1, the more priority selection factor is the number of $1-hop$ neighbours, $NBR j$, which can minimize the energy consumption during the communication Significantly.
713 \subsection{Decision phase}
715 Each WSNL will \textcolor{red}{ execute an optimization algorithm (see section \ref{oa})} to select which cover sets will be
716 activated in the following sensing phase to cover the subregion to which it
717 belongs. The \textcolor{red}{optimization algorithm} will produce $T$ cover sets, one for each round. The WSNL will send an Active-Sleep packet to each sensor in the subregion based on the algorithm's results, indicating if the sensor should be active or not in
718 each round of the sensing phase.
720 %solve an integer program
722 \subsection{Sensing phase}
724 The sensing phase consists of $T$ rounds. Each sensor node in the subregion will
725 receive an Active-Sleep packet from WSNL, informing it to stay awake or to go to
726 sleep for each round of the sensing phase. Algorithm~\ref{alg:MuDiLCO}, which
727 will be executed by each node at the beginning of a period, explains how the
728 Active-Sleep packet is obtained.
730 % In each round during the sensing phase, there is a cover set of sensor nodes, in which the active sensors will execute their sensing task to preserve maximal coverage and lifetime in the subregion and this will continue until finishing the round $T$ and starting new period.
732 \begin{algorithm}[h!]
733 % \KwIn{all the parameters related to information exchange}
734 % \KwOut{$winer-node$ (: the id of the winner sensor node, which is the leader of current round)}
736 %\emph{Initialize the sensor node and determine it's position and subregion} \;
738 \If{ $RE_j \geq E_{R}$ }{
739 \emph{$s_j.status$ = COMMUNICATION}\;
740 \emph{Send $INFO()$ packet to other nodes in the subregion}\;
741 \emph{Wait $INFO()$ packet from other nodes in the subregion}\;
742 %\emph{UPDATE $RE_j$ for every sent or received INFO Packet}\;
743 %\emph{ Collect information and construct the list L for all nodes in the subregion}\;
745 %\If{ the received INFO Packet = No. of nodes in it's subregion -1 }{
746 \emph{LeaderID = Leader election}\;
747 \If{$ s_j.ID = LeaderID $}{
748 \emph{$s_j.status$ = COMPUTATION}\;
749 \emph{$\left\{\left(X_{1,k},\dots,X_{T,k}\right)\right\}_{k \in J}$ =
750 Execute \textcolor{red}{Optimization Algorithm}($T,J$)}\;
751 \emph{$s_j.status$ = COMMUNICATION}\;
752 \emph{Send $ActiveSleep()$ to each node $k$ in subregion a packet \\
753 with vector of activity scheduling $(X_{1,k},\dots,X_{T,k})$}\;
754 \emph{Update $RE_j $}\;
757 \emph{$s_j.status$ = LISTENING}\;
758 \emph{Wait $ActiveSleep()$ packet from the Leader}\;
759 % \emph{After receiving Packet, Retrieve the schedule and the $T$ rounds}\;
760 \emph{Update $RE_j $}\;
764 \Else { Exclude $s_j$ from entering in the current sensing phase}
767 \caption{MuDiLCO($s_j$)}
777 \section{\textcolor{red}{ Optimization Algorithm for Multiround Lifetime Coverage Optimization}}
779 As shown in Algorithm~\ref{alg:MuDiLCO}, the leader will execute an optimization algorithm based on an integer program. The integer program is based on the model
780 proposed by \cite{pedraza2006} with some modifications, where the objective is
781 to find a maximum number of disjoint cover sets. To fulfill this goal, the
782 authors proposed an integer program which forces undercoverage and overcoverage
783 of targets to become minimal at the same time. They use binary variables
784 $x_{jl}$ to indicate if sensor $j$ belongs to cover set $l$. In our model, we
785 consider binary variables $X_{t,j}$ to determine the possibility of activating
786 sensor $j$ during round $t$ of a given sensing phase. We also consider primary
787 points as targets. The set of primary points is denoted by $P$ and the set of
788 sensors by $J$. Only sensors able to be alive during at least one round are
789 involved in the integer program.
791 %parler de la limite en energie Et pour un round
793 For a primary point $p$, let $\alpha_{j,p}$ denote the indicator function of
794 whether the point $p$ is covered, that is:
796 \alpha_{j,p} = \left \{
798 1 & \mbox{if the primary point $p$ is covered} \\
799 & \mbox{by sensor node $j$}, \\
800 0 & \mbox{otherwise.}\\
804 The number of active sensors that cover the primary point $p$ during
805 round $t$ is equal to $\sum_{j \in J} \alpha_{j,p} * X_{t,j}$ where:
809 1& \mbox{if sensor $j$ is active during round $t$,} \\
810 0 & \mbox{otherwise.}\\
814 We define the Overcoverage variable $\Theta_{t,p}$ as:
816 \Theta_{t,p} = \left \{
818 0 & \mbox{if the primary point $p$}\\
819 & \mbox{is not covered during round $t$,}\\
820 \left( \sum_{j \in J} \alpha_{jp} * X_{tj} \right)- 1 & \mbox{otherwise.}\\
824 More precisely, $\Theta_{t,p}$ represents the number of active sensor nodes
825 minus one that cover the primary point $p$ during round $t$. The
826 Undercoverage variable $U_{t,p}$ of the primary point $p$ during round $t$ is
831 1 &\mbox{if the primary point $p$ is not covered during round $t$,} \\
832 0 & \mbox{otherwise.}\\
837 Our coverage optimization problem can then be formulated as follows:
839 \min \sum_{t=1}^{T} \sum_{p=1}^{P} \left(W_{\theta}* \Theta_{t,p} + W_{U} * U_{t,p} \right) \label{eq15}
844 \sum_{j=1}^{|J|} \alpha_{j,p} * X_{t,j} = \Theta_{t,p} - U_{t,p} + 1 \label{eq16} \hspace{6 mm} \forall p \in P, t = 1,\dots,T
848 \sum_{t=1}^{T} X_{t,j} \leq \floor*{RE_{j}/E_{R}} \hspace{6 mm} \forall j \in J, t = 1,\dots,T
853 X_{t,j} \in \lbrace0,1\rbrace, \hspace{10 mm} \forall j \in J, t = 1,\dots,T \label{eq17}
857 U_{t,p} \in \lbrace0,1\rbrace, \hspace{10 mm}\forall p \in P, t = 1,\dots,T \label{eq18}
861 \Theta_{t,p} \geq 0 \hspace{10 mm}\forall p \in P, t = 1,\dots,T \label{eq178}
865 %(W_{\theta}+W_{\psi} = P) \label{eq19}
868 %%RC why W_{\theta} is not defined (only one sentence)? How to define in practice Wtheta and Wu?
871 \item $X_{t,j}$: indicates whether or not the sensor $j$ is actively sensing
872 during round $t$ (1 if yes and 0 if not);
873 \item $\Theta_{t,p}$ - {\it overcoverage}: the number of sensors minus one that
874 are covering the primary point $p$ during round $t$;
875 \item $U_{t,p}$ - {\it undercoverage}: indicates whether or not the primary
876 point $p$ is being covered during round $t$ (1 if not covered and 0 if
880 The first group of constraints indicates that some primary point $p$ should be
881 covered by at least one sensor and, if it is not always the case, overcoverage
882 and undercoverage variables help balancing the restriction equations by taking
883 positive values. The constraint given by equation~(\ref{eq144}) guarantees that
884 the sensor has enough energy ($RE_j$ corresponds to its remaining energy) to be
885 alive during the selected rounds knowing that $E_{R}$ is the amount of energy
886 required to be alive during one round.
888 There are two main objectives. First, we limit the overcoverage of primary
889 points in order to activate a minimum number of sensors. Second we prevent the
890 absence of monitoring on some parts of the subregion by minimizing the
891 undercoverage. The weights $W_\theta$ and $W_U$ must be properly chosen so as
892 to guarantee that the maximum number of points are covered during each round.
893 %% MS W_theta is smaller than W_u => problem with the following sentence
894 In our simulations priority is given to the coverage by choosing $W_{U}$ very
895 large compared to $W_{\theta}$.
896 %The Active-Sleep packet includes the schedule vector with the number of rounds that should be applied by the receiving sensor node during the sensing phase.
898 \textcolor{red}{This integer program can be solved using two approaches:}
900 \subsection{\textcolor{red}{Optimization solver for Multiround Lifetime Coverage Optimization}}
902 \textcolor{red}{The modeling language for Mathematical Programming (AMPL)~\cite{AMPL} is employed to generate the integer program instance in a standard format, which is then read and solved by the optimization solver GLPK (GNU linear Programming Kit available in the public domain) \cite{glpk} through a Branch-and-Bound method. We named the protocol which is based on GLPK solver in the decision phase as MuDiLCO.}
907 \subsection{\textcolor{red}{Genetic Algorithm for Multiround Lifetime Coverage Optimization}}
909 \textcolor{red}{Metaheuristics are a generic search strategies for exploring search spaces for solving the complex problems. These strategies have to dynamically balance between the exploitation of the accumulated search experience and the exploration of the search space. On one hand, this balance can find regions in the search space with high-quality solutions. On the other hand, it prevents waste too much time in regions of the search space which are either already explored or don’t provide high-quality solutions. Therefore, metaheuristic provides an enough good solution to an optimization problem, especially with incomplete information or limited computation capacity \cite{bianchi2009survey}. Genetic Algorithm (GA) is one of the population-based metaheuristic methods that simulates the process of natural selection \cite{hassanien2015applications}. GA starts with a population of random candidate solutions (called individuals or phenotypes) . GA uses genetic operators inspired by natural evolution, such as selection, mutation, evaluation, crossover, and replacement so as to improve the initial population of candidate solutions. This process repeated until a stopping criterion is satisfied. In comparison with GLPK optimization solver, GA provides a near optimal solution with acceptable execution time, as well as it requires a less amount of memory especially for large size problems. GLPK provides optimal solution, but it requires higher execution time and amount of memory for large problem.}
911 \textcolor{red}{In this section, we present a metaheuristic based GA to solve our multiround lifetime coverage optimization problem. The proposed GA provides a near optimal sechedule for multiround sensing per period. The proposed GA is based on the mathematical model which is presented in Section \ref{oa}. Algorithm \ref{alg:GA} shows the proposed GA to solve the coverage lifetime optimization problem. We named the new protocol which is based on GA in the decision phase as GA-MuDiLCO. The proposed GA can be explained in more details as follow:}
913 \begin{algorithm}[h!]
916 \SetKwInput{Input}{\textcolor{red}{Input}}
917 \SetKwInput{Output}{\textcolor{red}{Output}}
918 \Input{ \textcolor{red}{$ P, J, T, S_{pop}, \alpha_{j,p}^{ind}, X_{t,j}^{ind}, \Theta_{t,p}^{ind}, U_{t,p}^{ind}, Child_{t,j}^{ind}, Ch.\Theta_{t,p}^{ind}, Ch.U_{t,p}^{ind_1}$}}
919 \Output{\textcolor{red}{$\left\{\left(X_{1,1},\dots, X_{t,j}, \dots, X_{T,J}\right)\right\}_{t \in T, j \in J}$}}
922 %\emph{Initialize the sensor node and determine it's position and subregion} \;
923 \ForEach {\textcolor{red}{Individual $ind$ $\in$ $S_{pop}$}} {
924 \emph{\textcolor{red}{Generate Randomly Chromosome $\left\{\left(X_{1,1},\dots, X_{t,j}, \dots, X_{T,J}\right)\right\}_{t \in T, j \in J}$}}\;
926 \emph{\textcolor{red}{Update O-U-Coverage $\left\{(P, J, \alpha_{j,p}^{ind}, X_{t,j}^{ind}, \Theta_{t,p}^{ind}, U_{t,p}^{ind})\right\}_{p \in P}$}}\;
929 \emph{\textcolor{red}{Evaluate Individual $(P, J, X_{t,j}^{ind}, \Theta_{t,p}^{ind}, U_{t,p}^{ind})$}}\;
932 \While{\textcolor{red}{ Stopping criteria is not satisfied} }{
934 \emph{\textcolor{red}{Selection $(ind_1, ind_2)$}}\;
935 \emph{\textcolor{red}{Crossover $(P_c, X_{t,j}^{ind_1}, X_{t,j}^{ind_2}, Child_{t,j}^{ind_1}, Child_{t,j}^{ind_2})$}}\;
936 \emph{\textcolor{red}{Mutation $(P_m, Child_{t,j}^{ind_1}, Child_{t,j}^{ind_2})$}}\;
939 \emph{\textcolor{red}{Update O-U-Coverage $(P, J, \alpha_{j,p}^{ind}, Child_{t,j}^{ind_1}, Ch.\Theta_{t,p}^{ind_1}, Ch.U_{t,p}^{ind_1})$}}\;
940 \emph{\textcolor{red}{Update O-U-Coverage $(P, J, \alpha_{j,p}^{ind}, Child_{t,j}^{ind_2}, Ch.\Theta_{t,p}^{ind_2}, Ch.U_{t,p}^{ind_2})$}}\;
942 \emph{\textcolor{red}{Evaluate New Individual$(P, J, Child_{t,j}^{ind_1}, Ch.\Theta_{t,p}^{ind_1}, Ch.U_{t,p}^{ind_1})$}}\;
943 \emph{\textcolor{red}{Replacement $(P, J, T, Child_{t,j}^{ind_1}, Ch.\Theta_{t,p}^{ind_1}, Ch.U_{t,p}^{ind_1}, X_{t,j}^{ind}, \Theta_{t,p}^{ind}, U_{t,p}^{ind} )$ }}\;
945 \emph{\textcolor{red}{Evaluate New Individual$(P, J, Child_{t,j}^{ind_2}, Ch.\Theta_{t,p}^{ind_2}, Ch.U_{t,p}^{ind_2})$}}\;
947 \emph{\textcolor{red}{Replacement $(P, J, T, Child_{t,j}^{ind_2}, Ch.\Theta_{t,p}^{ind_2}, Ch.U_{t,p}^{ind_2}, X_{t,j}^{ind}, \Theta_{t,p}^{ind}, U_{t,p}^{ind} )$ }}\;
951 \emph{\textcolor{red}{$\left\{\left(X_{1,1},\dots,X_{t,j},\dots,X_{T,J}\right)\right\}$ =
952 Select Best Solution ($S_{pop}$)}}\;
953 \emph{\textcolor{red}{return X}} \;
954 \caption{\textcolor{red}{GA($T, J$)}}
960 \begin{enumerate} [I)]
962 \item \textcolor{red}{\textbf{Representation:} Since the proposed GA's goal is to find the optimal schedule of the sensor nodes which take the responsibility of monitoring the subregion for $T$ rounds in the sensing phase, the chromosome is defined as a schedule for alive sensors and each chromosome contains $T$ rounds. The proposed GA uses binary representation, where each round in the schedule includes J genes, the total alive sensors in the subregion. Therefore, the gene of such a chromosome is a schedule of a sensor. In other words, The genes corresponding to active nodes have the value of one, the others are zero. Figure \ref{chromo} shows solution representation in the proposed GA.}
966 \includegraphics [scale=0.35] {rep.pdf}
967 \caption{Candidate Solution representation by the proposed GA. }
973 \item \textcolor{red}{\textbf{Initialize Population:} The initial population is randomly generated and each chromosome in the GA population represents a possible sensors schedule solution to cover the entire subregion for $T$ rounds during current period. Each sensor in the chromosome is given a random value (0 or 1) for all rounds. If the random value is 1, the remaining energy of this sensor should be adequate to activate this sensor during the current round. Otherwise, the value is set to 0. The energy constraint is applied for each sensor during all rounds. }
976 \item \textcolor{red}{\textbf{Update O-U-Coverage:}
977 After creating the initial population, The overcoverage $\Theta_{t,p}$ and undercoverage $U_{t,p}$ for each candidate solution are computed (see Algorithm \ref{OU}) so as to use them in the next step.}
979 \begin{algorithm}[h!]
981 \SetKwInput{Input}{\textcolor{red}{Input}}
982 \SetKwInput{Output}{\textcolor{red}{Output}}
983 \Input{ \textcolor{red}{parameters $P, J, ind, \alpha_{j,p}^{ind}, X_{t,j}^{ind}$}}
984 \Output{\textcolor{red}{$U^{ind} = \left\lbrace U_{1,1}^{ind}, \dots, U_{t,p}^{ind}, \dots, U_{T,P}^{ind} \right\rbrace$ and $\Theta^{ind} = \left\lbrace \Theta_{1,1}^{ind}, \dots, \Theta_{t,p}^{ind}, \dots, \Theta_{T,P}^{ind} \right\rbrace$}}
988 \For{\textcolor{red}{$t\leftarrow 1$ \KwTo $T$}}{
989 \For{\textcolor{red}{$p\leftarrow 1$ \KwTo $P$}}{
991 % \For{$i\leftarrow 0$ \KwTo $I_j$}{
992 \emph{\textcolor{red}{$SUM\leftarrow 0$}}\;
993 \For{\textcolor{red}{$j\leftarrow 1$ \KwTo $J$}}{
994 \emph{\textcolor{red}{$SUM \leftarrow SUM + (\alpha_{j,p}^{ind} \times X_{t,j}^{ind})$ }}\;
997 \If { \textcolor{red}{SUM = 0}} {
998 \emph{\textcolor{red}{$U_{t,p}^{ind} \leftarrow 0$}}\;
999 \emph{\textcolor{red}{$\Theta_{t,p}^{ind} \leftarrow 1$}}\;
1002 \emph{\textcolor{red}{$U_{t,p}^{ind} \leftarrow SUM -1$}}\;
1003 \emph{\textcolor{red}{$\Theta_{t,p}^{ind} \leftarrow 0$}}\;
1009 \emph{\textcolor{red}{return $U^{ind}, \Theta^{ind}$ }} \;
1010 \caption{O-U-Coverage}
1017 \item \textcolor{red}{\textbf{Evaluate Population:}
1018 After creating the initial population, each individual is evaluated and assigned a fitness value according to the fitness function is illustrated in Eq. \eqref{eqf}. In the proposed GA, the optimal (or near optimal) candidate solution, is the one with the minimum value for the fitness function. The lower the fitness values been assigned to an individual, the better opportunity it gets survived. In our works, the function rewards the decrease in the sensor nodes which cover the same primary point and penalizes the decrease to zero in the sensor nodes which cover the primary point. }
1021 F^{ind} \leftarrow \sum_{t=1}^{T} \sum_{p=1}^{P} \left(W_{\theta}* \Theta_{t,p} + W_{U} * U_{t,p} \right) \label{eqf}
1025 \item \textcolor{red}{\textbf{Selection:} In order to generate a new generation, a portion of the existing population is elected based on a fitness function that ranks the fitness of each candidate solution and preferentially select the best solutions. Two parents should be selected to the mating pool. In the proposed GA-MuDiLCO algorithm, the first parent is selected by using binary tournament selection to select one of the parents \cite{goldberg1991comparative}. In this method, two individuals are chosen at random from the population and the better of the two
1026 individuals is selected. If they have similar fitness values, one of them will be selected randomly. The best individual in the population is selected as a second parent.}
1030 \item \textcolor{red}{\textbf{Crossover:} Crossover is a genetic operator used to take more than one parent solutions and produce a child solution from them. If crossover probability $P_c$ is 100$\%$, then the crossover operation takes place between two individuals. If it is 0$\%$, the two selected individuals in the mating pool will be the new chromosomes without crossover. In the proposed GA, a two-point crossover is used. Figure \ref{cross} gives an example for a two-point crossover for 8 sensors in the subregion and the schedule for 3 rounds.}
1035 \includegraphics [scale = 0.3] {crossover.pdf}
1036 \caption{Two-point crossover. }
1041 \item \textcolor{red}{\textbf{Mutation:}
1042 Mutation is a divergence operation which introduces random modifications. The purpose of the mutation is to maintain diversity within the population and prevent premature convergence. Mutation is used to add new genetic information (divergence) in order to achieve a global search over the solution search space and avoid to fall in local optima. The mutation operator in the proposed GA-MuDiLCO works as follow: If mutation probability $P_m$ is 100$\%$, then the mutation operation takes place on the new individual. The round number is selected randomly within (1..T) in the schedule solution. After that one sensor within this round is selected randomly within (1..J). If the sensor is scheduled as active "1", it should be rescheduled to sleep "0". If the sensor is scheduled as sleep, it rescheduled to active only if it has adequate remaining energy.}
1045 \item \textcolor{red}{\textbf{Update O-U-Coverage for children:}
1046 Before evaluating each new individual, Algorithm \ref{OU} is called for each new individual to compute the new undercoverage $Ch.U$ and overcoverage $Ch.\Theta$ parameters. }
1048 \item \textcolor{red}{\textbf{Evaluate New Individuals:}
1049 Each new individual is evaluated using Eq. \ref{eqf} but with using the new undercoverage $Ch.U$ and overcoverage $Ch.\Theta$ parameters of the new children.}
1051 \item \textcolor{red}{\textbf{Replacement:}
1052 After evaluation of new children, Triple Tournament Replacement (TTR) will be applied for each new individual. In TTR strategy, three individuals are selected
1053 randomly from the population. Find the worst from them and then check its fitness with the new individual fitness. If the fitness of the new individual is better than the fitness of the worst individual, replace the new individual with the worst individual. Otherwise, the replacement is not done. }
1056 \item \textcolor{red}{\textbf{Stopping criteria:}
1057 The proposed GA-MuDiLCO stops when the stopping criteria is met. It stops after running for an amount of time in seconds equal to \textbf{Time limit}. The \textbf{Time limit} is the execution time obtained by the optimization solver GLPK for solving the same size of problem. The best solution will be selected as a schedule of sensors for $T$ rounds during the sensing phase in the current period.}
1065 \section{Experimental study}
1067 \subsection{Simulation setup}
1069 We conducted a series of simulations to evaluate the efficiency and the
1070 relevance of our approach, using the discrete event simulator OMNeT++
1071 \cite{varga}. The simulation parameters are summarized in
1072 Table~\ref{table3}. Each experiment for a network is run over 25~different
1073 random topologies and the results presented hereafter are the average of these
1075 %Based on the results of our proposed work in~\cite{idrees2014coverage}, we found as the region of interest are divided into larger subregions as the network lifetime increased. In this simulation, the network are divided into 16 subregions.
1076 We performed simulations for five different densities varying from 50 to
1077 250~nodes deployed over a $50 \times 25~m^2 $ sensing field. More
1078 precisely, the deployment is controlled at a coarse scale in order to ensure
1079 that the deployed nodes can cover the sensing field with the given sensing
1082 %%RC these parameters are realistic?
1083 %% maybe we can increase the field and sensing range. 5mfor Rs it seems very small... what do the other good papers consider ?
1086 \caption{Relevant parameters for network initializing.}
1089 % used for centering table
1090 \begin{tabular}{c|c}
1091 % centered columns (4 columns)
1093 %inserts double horizontal lines
1094 Parameter & Value \\ [0.5ex]
1096 %Case & Strategy (with Two Leaders) & Strategy (with One Leader) & Simple Heuristic \\ [0.5ex]
1100 % inserts single horizontal line
1101 Sensing field size & $(50 \times 25)~m^2 $ \\
1102 % inserting body of the table
1104 Network size & 50, 100, 150, 200 and 250~nodes \\
1106 Initial energy & 500-700~joules \\
1108 Sensing time for one round & 60 Minutes \\
1109 $E_{R}$ & 36 Joules\\
1113 % [1ex] adds vertical space
1115 $W_{U}$ & $|P|^2$ \\
1119 %inserts single line
1122 % is used to refer this table in the text
1125 \textcolor{red}{Our first protocol based GLPK optimization solver is declined into four versions: MuDiLCO-1, MuDiLCO-3, MuDiLCO-5,
1126 and MuDiLCO-7, corresponding respectively to $T=1,3,5,7$ ($T$ the number of
1127 rounds in one sensing period). The second protocol based GA is declined into four versions: GA-MuDiLCO-1, GA-MuDiLCO-3, GA-MuDiLCO-5,
1128 and GA-MuDiLCO-7 for the same reason of the first protocol. After extensive experiments, we chose the dedicated values for the parameters $P_c$, $P_m$, and $S_{pop}$ because they gave the best results}. In the following, we will make comparisons with
1129 two other methods. The first method, called DESK and proposed by \cite{ChinhVu},
1130 is a full distributed coverage algorithm. The second method, called
1131 GAF~\cite{xu2001geography}, consists in dividing the region into fixed squares.
1132 During the decision phase, in each square, one sensor is then chosen to remain
1133 active during the sensing phase time.
1135 Some preliminary experiments were performed to study the choice of the number of
1136 subregions which subdivides the sensing field, considering different network
1137 sizes. They show that as the number of subregions increases, so does the network
1138 lifetime. Moreover, it makes the MuDiLCO protocol more robust against random
1139 network disconnection due to node failures. However, too many subdivisions
1140 reduce the advantage of the optimization. In fact, there is a balance between
1141 the benefit from the optimization and the execution time needed to solve
1142 it. Therefore, we have set the number of subregions to 16 rather than 32.
1144 \subsection{Energy model}
1146 We use an energy consumption model proposed by~\cite{ChinhVu} and based on
1147 \cite{raghunathan2002energy} with slight modifications. The energy consumption
1148 for sending/receiving the packets is added, whereas the part related to the
1149 sensing range is removed because we consider a fixed sensing range.
1151 % We are took into account the energy consumption needed for the high computation during executing the algorithm on the sensor node.
1152 %The new energy consumption model will take into account the energy consumption for communication (packet transmission/reception), the radio of the sensor node, data sensing, computational energy of Micro-Controller Unit (MCU) and high computation energy of MCU.
1155 For our energy consumption model, we refer to the sensor node Medusa~II which
1156 uses an Atmels AVR ATmega103L microcontroller~\cite{raghunathan2002energy}. The
1157 typical architecture of a sensor is composed of four subsystems: the MCU
1158 subsystem which is capable of computation, communication subsystem (radio) which
1159 is responsible for transmitting/receiving messages, the sensing subsystem that
1160 collects data, and the power supply which powers the complete sensor node
1161 \cite{raghunathan2002energy}. Each of the first three subsystems can be turned
1162 on or off depending on the current status of the sensor. Energy consumption
1163 (expressed in milliWatt per second) for the different status of the sensor is
1164 summarized in Table~\ref{table4}.
1167 \caption{The Energy Consumption Model}
1170 % used for centering table
1171 \begin{tabular}{|c|c|c|c|c|}
1172 % centered columns (4 columns)
1174 %inserts double horizontal lines
1175 Sensor status & MCU & Radio & Sensing & Power (mW) \\ [0.5ex]
1177 % inserts single horizontal line
1178 LISTENING & on & on & on & 20.05 \\
1179 % inserting body of the table
1181 ACTIVE & on & off & on & 9.72 \\
1183 SLEEP & off & off & off & 0.02 \\
1185 COMPUTATION & on & on & on & 26.83 \\
1187 %\multicolumn{4}{|c|}{Energy needed to send/receive a 1-bit} & 0.2575\\
1192 % is used to refer this table in the text
1195 For the sake of simplicity we ignore the energy needed to turn on the radio, to
1196 start up the sensor node, to move from one status to another, etc.
1197 %We also do not consider the need of collecting sensing data. PAS COMPRIS
1198 Thus, when a sensor becomes active (i.e., it has already chosen its status), it can
1199 turn its radio off to save battery. MuDiLCO uses two types of packets for
1200 communication. The size of the INFO packet and Active-Sleep packet are 112~bits
1201 and 24~bits respectively. The value of energy spent to send a 1-bit-content
1202 message is obtained by using the equation in ~\cite{raghunathan2002energy} to
1203 calculate the energy cost for transmitting messages and we propose the same
1204 value for receiving the packets. The energy needed to send or receive a 1-bit
1205 packet is equal to 0.2575~mW.
1207 The initial energy of each node is randomly set in the interval $[500;700]$. A
1208 sensor node will not participate in the next round if its remaining energy is
1209 less than $E_{R}=36~\mbox{Joules}$, the minimum energy needed for the node to
1210 stay alive during one round. This value has been computed by multiplying the
1211 energy consumed in active state (9.72 mW) by the time in second for one round
1212 (3600 seconds). According to the interval of initial energy, a sensor may be
1213 alive during at most 20 rounds.
1215 \subsection{Metrics}
1217 To evaluate our approach we consider the following performance metrics:
1219 \begin{enumerate}[i]
1221 \item {{\bf Coverage Ratio (CR)}:} the coverage ratio measures how much of the area
1222 of a sensor field is covered. In our case, the sensing field is represented as
1223 a connected grid of points and we use each grid point as a sample point to
1224 compute the coverage. The coverage ratio can be calculated by:
1227 \mbox{CR}(\%) = \frac{\mbox{$n^t$}}{\mbox{$N$}} \times 100,
1229 where $n^t$ is the number of covered grid points by the active sensors of all
1230 subregions during round $t$ in the current sensing phase and $N$ is the total number
1231 of grid points in the sensing field of the network. In our simulations $N = 51
1232 \times 26 = 1326$ grid points.
1233 %The accuracy of this method depends on the distance between grids. In our
1234 %simulations, the sensing field has been divided into 50 by 25 grid points, which means
1235 %there are $51 \times 26~ = ~ 1326$ points in total.
1236 % Therefore, for our simulations, the error in the coverage calculation is less than ~ 1 $\% $.
1238 \item{{\bf Number of Active Sensors Ratio (ASR)}:} it is important to have as
1239 few active nodes as possible in each round, in order to minimize the
1240 communication overhead and maximize the network lifetime. The Active Sensors
1241 Ratio is defined as follows:
1243 \scriptsize \mbox{ASR}(\%) = \frac{\sum\limits_{r=1}^R
1244 \mbox{$A_r^t$}}{\mbox{$|J|$}} \times 100,
1246 where $A_r^t$ is the number of active sensors in the subregion $r$ during round
1247 $t$ in the current sensing phase, $|J|$ is the total number of sensors in the
1248 network, and $R$ is the total number of subregions in the network.
1250 \item {{\bf Network Lifetime}:} we define the network lifetime as the time until
1251 the coverage ratio drops below a predefined threshold. We denote by
1252 $Lifetime_{95}$ (respectively $Lifetime_{50}$) the amount of time during
1253 which the network can satisfy an area coverage greater than $95\%$
1254 (respectively $50\%$). We assume that the network is alive until all nodes have
1255 been drained of their energy or the sensor network becomes
1256 disconnected. Network connectivity is important because an active sensor node
1257 without connectivity towards a base station cannot transmit information on an
1258 event in the area that it monitors.
1260 \item {{\bf Energy Consumption (EC)}:} the average energy consumption can be
1261 seen as the total energy consumed by the sensors during the $Lifetime_{95}$ or
1262 $Lifetime_{50}$ divided by the number of rounds. EC can be computed as
1265 % New version with global loops on period
1268 \mbox{EC} = \frac{\sum\limits_{m=1}^{M} \left[ \left( E^{\mbox{com}}_m+E^{\mbox{list}}_m+E^{\mbox{comp}}_m \right) +\sum\limits_{t=1}^{T_m} \left( E^{a}_t+E^{s}_t \right) \right]}{\sum\limits_{m=1}^{M} T_m},
1272 % Old version with loop on round outside the loop on period
1275 % \mbox{EC} = \frac{\sum\limits_{m=1}^{M_L} \left( E^{\mbox{com}}_m+E^{\mbox{list}}_m+E^{\mbox{comp}}_m \right) +\sum\limits_{t=1}^{T_L} \left( E^{a}_t+E^{s}_t \right)}{T_L},
1281 %\mbox{EC} = \frac{\mbox{$\sum\limits_{d=1}^D E^c_d$}}{\mbox{$D$}} + \frac{\mbox{$\sum\limits_{d=1}^D %E^l_d$}}{\mbox{$D$}} + \frac{\mbox{$\sum\limits_{d=1}^D E^a_d$}}{\mbox{$D$}} + %\frac{\mbox{$\sum\limits_{d=1}^D E^s_d$}}{\mbox{$D$}}.
1284 % Old version -> where $M_L$ and $T_L$ are respectively the number of periods and rounds during
1285 %$Lifetime_{95}$ or $Lifetime_{50}$.
1287 where $M$ is the number of periods and $T_m$ the number of rounds in a
1288 period~$m$, both during $Lifetime_{95}$ or $Lifetime_{50}$. The total energy
1289 consumed by the sensors (EC) comes through taking into consideration four main
1290 energy factors. The first one , denoted $E^{\scriptsize \mbox{com}}_m$,
1291 represents the energy consumption spent by all the nodes for wireless
1292 communications during period $m$. $E^{\scriptsize \mbox{list}}_m$, the next
1293 factor, corresponds to the energy consumed by the sensors in LISTENING status
1294 before receiving the decision to go active or sleep in period $m$.
1295 $E^{\scriptsize \mbox{comp}}_m$ refers to the energy needed by all the leader
1296 nodes to solve the integer program during a period. Finally, $E^a_t$ and $E^s_t$
1297 indicate the energy consumed by the whole network in round $t$.
1299 %\item {Network Lifetime:} we have defined the network lifetime as the time until all
1300 %nodes have been drained of their energy or each sensor network monitoring an area has become disconnected.
1302 \item {{\bf Execution Time}:} a sensor node has limited energy resources and
1303 computing power, therefore it is important that the proposed algorithm has the
1304 shortest possible execution time. The energy of a sensor node must be mainly
1305 used for the sensing phase, not for the pre-sensing ones.
1307 \item {{\bf Stopped simulation runs}:} a simulation ends when the sensor network
1308 becomes disconnected (some nodes are dead and are not able to send information
1309 to the base station). We report the number of simulations that are stopped due
1310 to network disconnections and for which round it occurs.
1314 \subsection{Results and analysis}
1316 \subsubsection{Coverage ratio}
1318 Figure~\ref{fig3} shows the average coverage ratio for 150 deployed nodes. We
1319 can notice that for the first thirty rounds both DESK and GAF provide a coverage
1320 which is a little bit better than the one of MuDiLCO.
1321 %%RC : need to uniformize MuDiLCO or MuDiLCO-T?
1322 %%MS : MuDiLCO everywhere
1323 %%RC maybe increase the size of the figure for the reviewers, no?
1324 This is due to the fact that, in comparison with MuDiLCO which uses optimization
1325 to put in SLEEP status redundant sensors, more sensor nodes remain active with
1326 DESK and GAF. As a consequence, when the number of rounds increases, a larger
1327 number of node failures can be observed in DESK and GAF, resulting in a faster
1328 decrease of the coverage ratio. Furthermore, our protocol allows to maintain a
1329 coverage ratio greater than 50\% for far more rounds. Overall, the proposed
1330 sensor activity scheduling based on optimization in MuDiLCO maintains higher
1331 coverage ratios of the area of interest for a larger number of rounds. It also
1332 means that MuDiLCO saves more energy, with less dead nodes, at most for several
1333 rounds, and thus should extend the network lifetime.
1337 \includegraphics[scale=0.5] {R/CR.pdf}
1338 \caption{Average coverage ratio for 150 deployed nodes}
1343 can see that for the first thirty nine rounds GA-MuDiLCO provides a little bit better coverage ratio than MuDiLCO. Both DESK and GAF provide a coverage
1344 which is a little bit better than the one of MuDiLCO and GA-MuDiLCO for the first thirty rounds because they activate a larger number of nodes during sensing phase. After that GA-MuDiLCO provides a coverage ratio near to the MuDiLCO and better than DESK and GAF. GA-MuDiLCO gives approximate solution with activation a larger number of nodes than MuDiLCO during sensing phase while it activates a less number of nodes in comparison with both DESK and GAF. MuDiLCO and GA-MuDiLCO clearly outperform DESK and GAF for
1345 a number of periods between 31 and 103. This is because they optimize the coverage and the lifetime in a wireless sensor network by selecting the best representative sensor nodes to take the responsibility of coverage during the sensing phase.}
1349 \subsubsection{Active sensors ratio}
1351 It is crucial to have as few active nodes as possible in each round, in order to
1352 minimize the communication overhead and maximize the network lifetime. Figure~\ref{fig4} presents the active sensor ratio for 150 deployed
1353 nodes all along the network lifetime. It appears that up to round thirteen, DESK
1354 and GAF have respectively 37.6\% and 44.8\% of nodes in ACTIVE status, whereas
1355 MuDiLCO clearly outperforms them with only 24.8\% of active nodes. \textcolor{red}{GA-MuDiLCO activates a number of sensor nodes larger than MuDiLCO but lower than both DESK and GAF. GA-MuDiLCO-1, GA-MuDiLCO-3, and GA-MuDiLCO-5 continue in providing a larger number of active sensors until the forty-sixth round after that it provides less number of active nodes due to the died nodes. GA-MuDiLCO-7 provides a larger number of sensor nodes and maintains a better coverage ratio compared to MuDiLCO-7 until the fifty-seventh round. After the thirty-fifth round, MuDiLCO exhibits larger numbers of active nodes compared with DESK and GAF, which agrees with the dual observation of higher level of coverage made previously}.
1356 Obviously, in that case DESK and GAF have less active nodes, since they have activated many nodes at the beginning. Anyway, MuDiLCO activates the available nodes in a more efficient manner. \textcolor{red}{GA-MuDiLCO activates near optimal number of sensor nodes also in efficient manner compared with both DESK and GAF}.
1360 \includegraphics[scale=0.5]{R/ASR.pdf}
1361 \caption{Active sensors ratio for 150 deployed nodes}
1365 %\textcolor{red}{GA-MuDiLCO activates a sensor nodes larger than MuDiLCO but lower than both DESK and GAF }
1368 \subsubsection{Stopped simulation runs}
1369 %The results presented in this experiment, is to show the comparison of our MuDiLCO protocol with other two approaches from the point of view the stopped simulation runs per round. Figure~\ref{fig6} illustrates the percentage of stopped simulation
1370 %runs per round for 150 deployed nodes.
1372 Figure~\ref{fig6} reports the cumulative percentage of stopped simulations runs
1373 per round for 150 deployed nodes. This figure gives the breakpoint for each method. DESK stops first, after approximately 45~rounds, because it consumes the
1374 more energy by turning on a large number of redundant nodes during the sensing
1375 phase. GAF stops secondly for the same reason than DESK. \textcolor{red}{GA-MuDiLCO stops thirdly for the same reason than DESK and GAF.} \textcolor{red}{MuDiLCO and GA-MuDiLCO overcome}
1376 DESK and GAF because \textcolor{red}{they activate less number of sensor nodes, as well as }the optimization process distributed on several subregions leads to coverage preservation and so extends the network lifetime.
1377 Let us emphasize that the simulation continues as long as a network in a subregion is still connected.
1379 %%% The optimization effectively continues as long as a network in a subregion is still connected. A VOIR %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
1383 \includegraphics[scale=0.5]{R/SR.pdf}
1384 \caption{Cumulative percentage of stopped simulation runs for 150 deployed nodes }
1388 \subsubsection{Energy consumption} \label{subsec:EC}
1390 We measure the energy consumed by the sensors during the communication,
1391 listening, computation, active, and sleep status for different network densities
1392 and compare it with the two other methods. Figures~\ref{fig7}(a)
1393 and~\ref{fig7}(b) illustrate the energy consumption, considering different
1394 network sizes, for $Lifetime_{95}$ and $Lifetime_{50}$.
1399 \parbox{9.5cm}{\includegraphics[scale=0.5]{R/EC95.pdf}} & (a) \\
1401 \parbox{9.5cm}{\includegraphics[scale=0.5]{R/EC50.pdf}} & (b)
1403 \caption{Energy consumption for (a) $Lifetime_{95}$ and
1404 (b) $Lifetime_{50}$}
1408 The results show that MuDiLCO is the most competitive from the energy
1409 consumption point of view. The other approaches have a high energy consumption
1410 due to activating a larger number of redundant nodes as well as the energy consumed during the different status of the sensor node. Among the different versions of our protocol, the MuDiLCO-7 one consumes more energy than the other
1411 versions. This is easy to understand since the bigger the number of rounds and the number of sensors involved in the integer program are, the larger the time computation to solve the optimization problem is. To improve the performances of MuDiLCO-7, we should increase the number of subregions in order to have less sensors to consider in the integer program.
1412 \textcolor{red}{As shown in Figure~\ref{fig7}, GA-MuDiLCO consumes less energy than both DESK and GAF, but a little bit higher than MuDiLCO because it provides a near optimal solution by activating a larger number of nodes during the sensing phase. GA-MuDiLCO consumes less energy in comparison with MuDiLCO-7 version, especially for the dense networks. However, MuDiLCO protocol and GA-MuDiLCO protocol are the most competitive from the energy
1413 consumption point of view. The other approaches have a high energy consumption
1414 due to activating a larger number of redundant nodes.}
1415 %In fact, a distributed optimization decision, which produces T rounds, on the subregions is greatly reduced the cost of communications and the time of listening as well as the energy needed for sensing phase and computation so thanks to the partitioning of the initial network into several independent subnetworks and producing T rounds for each subregion periodically.
1418 \subsubsection{Execution time}
1420 We observe the impact of the network size and of the number of rounds on the
1421 computation time. Figure~\ref{fig77} gives the average execution times in
1422 seconds (needed to solve optimization problem) for different values of $T$. The modeling language for Mathematical Programming (AMPL)~\cite{AMPL} is employed to generate the Mixed Integer Linear Program instance in a standard format, which is then read and solved by the optimization solver GLPK (GNU linear Programming Kit available in the public domain) \cite{glpk} through a Branch-and-Bound method. The
1423 original execution time is computed on a laptop DELL with Intel Core~i3~2370~M
1424 (2.4 GHz) processor (2 cores) and the MIPS (Million Instructions Per Second)
1425 rate equal to 35330. To be consistent with the use of a sensor node with Atmels
1426 AVR ATmega103L microcontroller (6 MHz) and a MIPS rate equal to 6 to run the
1427 optimization resolution, this time is multiplied by 2944.2 $\left(
1428 \frac{35330}{2} \times \frac{1}{6} \right)$ and reported on Figure~\ref{fig77}
1429 for different network sizes.
1433 \includegraphics[scale=0.5]{R/T.pdf}
1434 \caption{Execution Time (in seconds)}
1438 As expected, the execution time increases with the number of rounds $T$ taken
1439 into account to schedule the sensing phase. The times obtained for $T=1,3$
1440 or $5$ seem bearable, but for $T=7$ they become quickly unsuitable for a sensor
1441 node, especially when the sensor network size increases. Again, we can notice
1442 that if we want to schedule the nodes activities for a large number of rounds,
1443 we need to choose a relevant number of subregions in order to avoid a complicated
1444 and cumbersome optimization. On the one hand, a large value for $T$ permits to
1445 reduce the energy-overhead due to the three pre-sensing phases, on the other
1446 hand a leader node may waste a considerable amount of energy to solve the
1447 optimization problem.
1449 %While MuDiLCO-1, 3, and 5 solves the optimization process with suitable execution times to be used on wireless sensor network because it distributed on larger number of small subregions as well as it is used acceptable number of round(s) T. We think that in distributed fashion the solving of the optimization problem to produce T rounds in a subregion can be tackled by sensor nodes. Overall, to be able to deal with very large networks, a distributed method is clearly required.
1451 \subsubsection{Network lifetime}
1453 The next two figures, Figures~\ref{fig8}(a) and \ref{fig8}(b), illustrate the
1454 network lifetime for different network sizes, respectively for $Lifetime_{95}$
1455 and $Lifetime_{50}$. Both figures show that the network lifetime increases
1456 together with the number of sensor nodes, whatever the protocol, thanks to the
1457 node density which results in more and more redundant nodes that can be
1458 deactivated and thus save energy. Compared to the other approaches, our MuDiLCO
1459 protocol maximizes the lifetime of the network. In particular the gain in
1460 lifetime for a coverage over 95\% is greater than 38\% when switching from GAF
1461 to MuDiLCO-3. The slight decrease that can be observed for MuDiLCO-7 in case
1462 of $Lifetime_{95}$ with large wireless sensor networks results from the
1463 difficulty of the optimization problem to be solved by the integer program.
1464 This point was already noticed in subsection \ref{subsec:EC} devoted to the
1465 energy consumption, since network lifetime and energy consumption are directly
1466 linked. \textcolor{red}{As can be seen in these figures, the lifetime increases with the size of the network, and it is clearly largest for the MuDiLCO
1467 and the GA-MuDiLCO protocols. GA-MuDiLCO prolongs the network lifetime obviously in comparison with both DESK and GAF, as well as the MuDiLCO-7 version for $lifetime_{95}$. However, comparison shows that MuDiLCO protocol and GA-MuDiLCO protocol, which use distributed optimization over the subregions are the best ones because they are robust to network disconnection during the network lifetime as well as they consume less energy in comparison with other approaches.}
1471 \parbox{9.5cm}{\includegraphics[scale=0.5]{R/LT95.pdf}} & (a) \\
1473 \parbox{9.5cm}{\includegraphics[scale=0.5]{R/LT50.pdf}} & (b)
1475 \caption{Network lifetime for (a) $Lifetime_{95}$ and
1476 (b) $Lifetime_{50}$}
1480 % By choosing the best suited nodes, for each round, by optimizing the coverage and lifetime of the network to cover the area of interest with a maximum number rounds and by letting the other nodes sleep in order to be used later in next rounds, our MuDiLCO protocol efficiently prolonges the network lifetime.
1482 %In Figure~\ref{fig8}, Comparison shows that our MuDiLCO protocol, which are used distributed optimization on the subregions with the ability of producing T rounds, is the best one because it is robust to network disconnection during the network lifetime as well as it consume less energy in comparison with other approaches. It also means that distributing the protocol in each sensor node and subdividing the sensing field into many subregions, which are managed independently and simultaneously, is the most relevant way to maximize the lifetime of a network.
1485 %We see that our MuDiLCO-7 protocol results in execution times that quickly become unsuitable for a sensor network as well as the energy consumption seems to be huge because it used a larger number of rounds T during performing the optimization decision in the subregions, which is led to decrease the network lifetime. On the other side, our MuDiLCO-1, 3, and 5 protocol seems to be more efficient in comparison with other approaches because they are prolonged the lifetime of the network more than DESK and GAF.
1488 \section{Conclusion and future works}
1489 \label{sec:conclusion}
1491 We have addressed the problem of the coverage and of the lifetime optimization in
1492 wireless sensor networks. This is a key issue as sensor nodes have limited
1493 resources in terms of memory, energy, and computational power. To cope with this
1494 problem, the field of sensing is divided into smaller subregions using the
1495 concept of divide-and-conquer method, and then we propose a protocol which
1496 optimizes coverage and lifetime performances in each subregion. Our protocol,
1497 called MuDiLCO (Multiround Distributed Lifetime Coverage Optimization) combines
1498 two efficient techniques: network leader election and sensor activity
1500 %, where the challenges
1501 %include how to select the most efficient leader in each subregion and
1502 %the best cover sets %of active nodes that will optimize the network lifetime
1503 %while taking the responsibility of covering the corresponding
1504 %subregion using more than one cover set during the sensing phase.
1505 The activity scheduling in each subregion works in periods, where each period
1506 consists of four phases: (i) Information Exchange, (ii) Leader Election, (iii)
1507 Decision Phase to plan the activity of the sensors over $T$ rounds, (iv) Sensing
1508 Phase itself divided into $T$ rounds.
1510 Simulations results show the relevance of the proposed protocol in terms of
1511 lifetime, coverage ratio, active sensors ratio, energy consumption, execution
1512 time. Indeed, when dealing with large wireless sensor networks, a distributed
1513 approach, like the one we propose, allows to reduce the difficulty of a single
1514 global optimization problem by partitioning it in many smaller problems, one per
1515 subregion, that can be solved more easily. Nevertheless, results also show that
1516 it is not possible to plan the activity of sensors over too many rounds, because
1517 the resulting optimization problem leads to too high resolution times and thus to
1518 an excessive energy consumption.
1520 %In future work, we plan to study and propose adjustable sensing range coverage optimization protocol, which computes all active sensor schedules in one time, by using
1521 %optimization methods. This protocol can prolong the network lifetime by minimizing the number of the active sensor nodes near the borders by optimizing the sensing range of sensor nodes.
1522 % use section* for acknowledgement
1524 \section*{Acknowledgment}
1525 This work is partially funded by the Labex ACTION program (contract ANR-11-LABX-01-01).
1526 As a Ph.D. student, Ali Kadhum IDREES would like to gratefully acknowledge the
1527 University of Babylon - Iraq for the financial support, Campus France (The
1528 French national agency for the promotion of higher education, international
1529 student services, and international mobility).%, and the University ofFranche-Comt\'e - France for all the support in France.
1540 %% The Appendices part is started with the command \appendix;
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