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44 \journal{Journal of Supercomputing}
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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.}
87 \author{Ali Kadhum Idrees$^{a,b}$, Karine Deschinkel$^{a}$, \\
88 Michel Salomon$^{a}$, and Rapha\"el Couturier $^{a}$ \\
89 $^{a}${\em{FEMTO-ST Institute, DISC department, UMR 6174 CNRS, \\
90 Univ. Bourgogne Franche-Comt\'e (UBFC), Belfort, France}} \\
91 $^{b}${\em{Department of Computer Science, University of Babylon, Babylon, Iraq}}}
94 Coverage and lifetime are two paramount problems in Wireless Sensor Networks
95 (WSNs). In this paper, a method called Multiround Distributed Lifetime Coverage
96 Optimization protocol (MuDiLCO) is proposed to maintain the coverage and to
97 improve the lifetime in wireless sensor networks. The area of interest is first
98 divided into subregions and then the MuDiLCO protocol is distributed on the
99 sensor nodes in each subregion. The proposed MuDiLCO protocol works in periods
100 during which sets of sensor nodes are scheduled, with one set for each round of
101 a period, to remain active during the sensing phase and thus ensure coverage so
102 as to maximize the WSN lifetime. The decision process is carried out by a
103 leader node, which solves an optimization problem to produce the best
104 representative sets to be used during the rounds of the sensing phase. The
105 optimization problem formulated as an integer program is solved to optimality
106 through a Branch-and-Bound method for small instances. For larger instances,
107 the best feasible solution found by the solver after a given time limit
108 threshold is considered. Compared with some existing protocols, simulation
109 results based on multiple criteria (energy consumption, coverage ratio, and so
110 on) show that the proposed protocol can prolong efficiently the network lifetime
111 and improve the coverage performance.
115 Wireless Sensor Networks, Area Coverage, Network Lifetime,
116 Optimization, Scheduling, Distributed Computation.
121 \section{Introduction}
123 \indent The fast developments of low-cost sensor devices and wireless
124 communications have allowed the emergence of WSNs. A WSN includes a large number
125 of small, limited-power sensors that can sense, process, and transmit data over
126 a wireless communication. They communicate with each other by using multi-hop
127 wireless communications and cooperate together to monitor the area of interest,
128 so that each measured data can be reported to a monitoring center called sink
129 for further analysis~\cite{Sudip03}. There are several fields of application
130 covering a wide spectrum for a WSN, including health, home, environmental,
131 military, and industrial applications~\cite{Akyildiz02}.
133 On the one hand sensor nodes run on batteries with limited capacities, and it is
134 often costly or simply impossible to replace and/or recharge batteries,
135 especially in remote and hostile environments. Obviously, to achieve a long life
136 of the network it is important to conserve battery power. Therefore, lifetime
137 optimization is one of the most critical issues in wireless sensor networks. On
138 the other hand we must guarantee coverage over the area of interest. To fulfill
139 these two objectives, the main idea is to take advantage of overlapping sensing
140 regions to turn-off redundant sensor nodes and thus save energy. In this paper,
141 we concentrate on the area coverage problem, with the objective of maximizing
142 the network lifetime by using an optimized multiround scheduling.
144 The MuDiLCO protocol (for Multiround Distributed Lifetime Coverage Optimization
145 protocol) presented in this paper is an extension of the approach introduced
146 in~\cite{idrees2015distributed}.
147 % In~\cite{idrees2015distributed}, the protocol is
148 %deployed over only two subregions. Simulation results have shown that it was
149 %more interesting to divide the area into several subregions, given the
150 %computation complexity.
152 \textcolor{black}{ Compared to our previous work~\cite{idrees2015distributed},
153 in this paper we study the possibility of dividing the sensing phase into
154 multiple rounds. We make a multiround optimization,
155 while previously it was a single round optimization. The idea is to
156 take advantage of the pre-sensing phase to plan the sensor's activity for
157 several rounds instead of one, thus saving energy. In addition, when the
158 optimization problem becomes more complex, its resolution is stopped after a
159 given time threshold. In this paper we also analyze the performance of our
160 protocol according to the number of primary points used (the area coverage is
161 replaced by the coverage of a set of particular points called primary points,
162 see Section~\ref{pp}).}
164 The remainder of the paper is organized as follows. The next section reviews the
165 related works in the field. Section~\ref{pd} is devoted to the description of
166 MuDiLCO protocol. Section~\ref{exp} introduces the experimental framework, it
167 describes the simulation setup and the different metrics used to assess the
168 performances. Section~\ref{analysis} shows the simulation results obtained
169 using the discrete event simulator OMNeT++ \cite{varga}. They fully demonstrate
170 the usefulness of the proposed approach. Finally, we give concluding remarks
171 and some suggestions for future works in Section~\ref{sec:conclusion}.
173 \section{Related works}
176 \indent This section is dedicated to the various approaches proposed in the
177 literature for the coverage lifetime maximization problem, where the objective
178 is to optimally schedule sensors' activities in order to extend network lifetime
179 in WSNs. Cardei and Wu \cite{cardei2006energy} provide a taxonomy for coverage
180 algorithms in WSNs according to several design choices:
182 \item Sensors scheduling algorithm implementation, i.e. centralized or
183 distributed/localized algorithms.
184 \item The objective of sensor coverage, i.e. to maximize the network lifetime or
185 to minimize the number of active sensors during a sensing round.
186 \item The homogeneous or heterogeneous nature of the nodes, in terms of sensing
187 or communication capabilities.
188 \item The node deployment method, which may be random or deterministic.
189 \item Additional requirements for energy-efficient and connected coverage.
192 The choice of non-disjoint or disjoint cover sets (sensors participate or not in
193 many cover sets) can be added to the above list.
195 \subsection{Centralized approaches}
197 The major approach is to divide/organize the sensors into a suitable number of
198 cover sets where each set completely covers an interest region and to activate
199 these cover sets successively. The centralized algorithms always provide nearly
200 or close to optimal solution since the algorithm has global view of the whole
201 network. Note that centralized algorithms have the advantage of requiring very
202 low processing power from the sensor nodes, which usually have limited
203 processing capabilities. The main drawback of this kind of approach is its
204 higher cost in communications, since the node that will make the decision needs
205 information from all the sensor nodes. Exact or heuristic
206 approaches are designed to provide cover sets. Contrary to exact methods,
207 heuristic ones can handle very large and centralized problems. They are
208 proposed to reduce computational overhead such as energy consumption, delay,
209 and generally allow to increase the network lifetime.
211 The first algorithms proposed in the literature consider that the cover sets are
212 disjoint: a sensor node appears in exactly one of the generated cover
213 sets~\cite{abrams2004set,cardei2005improving,Slijepcevic01powerefficient}. In
214 the case of non-disjoint algorithms \cite{pujari2011high}, sensors may
215 participate in more than one cover set. In some cases, this may prolong the
216 lifetime of the network in comparison to the disjoint cover set algorithms, but
217 designing algorithms for non-disjoint cover sets generally induces a higher
218 order of complexity. Moreover, in case of a sensor's failure, non-disjoint
219 scheduling policies are less resilient and reliable because a sensor may be
220 involved in more than one cover sets.
222 In~\cite{yang2014maximum}, the authors have considered a linear programming
223 approach to select the minimum number of working sensor nodes, in order to
224 preserve a maximum coverage and to extend lifetime of the network. Cheng et
225 al.~\cite{cheng2014energy} have defined a heuristic algorithm called Cover Sets
226 Balance (CSB), which chooses a set of active nodes using the tuple (data
227 coverage range, residual energy). Then, they have introduced a new Correlated
228 Node Set Computing (CNSC) algorithm to find the correlated node set for a given
229 node. After that, they proposed a High Residual Energy First (HREF) node
230 selection algorithm to minimize the number of active nodes so as to prolong the
231 network lifetime. Various centralized methods based on column generation
232 approaches have also been
233 proposed~\cite{gentili2013,castano2013column,rossi2012exact,deschinkel2012column}.
234 In~\cite{gentili2013}, authors highlight the trade-off between
235 the network lifetime and the coverage percentage. They show that network
236 lifetime can be hugely improved by decreasing the coverage ratio.
238 \subsection{Distributed approaches}
240 In distributed and localized coverage algorithms, the required computation to
241 schedule the activity of sensor nodes will be done by the cooperation among
242 neighboring nodes. These algorithms may require more computation power for the
243 processing by the cooperating sensor nodes, but they are more scalable for large
244 WSNs. Localized and distributed algorithms generally result in non-disjoint set
247 Many distributed algorithms have been developed to perform the scheduling so as
248 to preserve coverage, see for example
249 \cite{Gallais06,Tian02,Ye03,Zhang05,HeinzelmanCB02, yardibi2010distributed,
250 prasad2007distributed,Misra}. Distributed algorithms typically operate in
251 rounds for a predetermined duration. At the beginning of each round, a sensor
252 exchanges information with its neighbors and makes a decision to either remain
253 turned on or to go to sleep for the round. This decision is basically made on
254 simple greedy criteria like the largest uncovered area
255 \cite{Berman05efficientenergy} or maximum uncovered targets
256 \cite{lu2003coverage}. The Distributed Adaptive Sleep Scheduling Algorithm
257 (DASSA) \cite{yardibi2010distributed} does not require location information of
258 sensors while maintaining connectivity and satisfying a user defined coverage
259 target. In DASSA, nodes use the residual energy levels and feedback from the
260 sink for scheduling the activity of their neighbors. This feedback mechanism
261 reduces the randomness in scheduling that would otherwise occur due to the
262 absence of location information. In \cite{ChinhVu}, the authors have designed a
263 novel distributed heuristic, called Distributed Energy-efficient Scheduling for
264 k-coverage (DESK), which ensures that the energy consumption among the sensors
265 is balanced and the lifetime maximized while the coverage requirement is
266 maintained. This heuristic works in rounds, requires only one-hop neighbor
267 information, and each sensor decides its status (active or sleep) based on the
268 perimeter coverage model from~\cite{Huang:2003:CPW:941350.941367}.
270 The works presented in \cite{Bang, Zhixin, Zhang} focus on coverage-aware,
271 distributed energy-efficient, and distributed clustering methods respectively,
272 which aim at extending the network lifetime, while the coverage is ensured.
273 More recently, Shibo et al. \cite{Shibo} have expressed the coverage problem as
274 a minimum weight submodular set cover problem and proposed a Distributed
275 Truncated Greedy Algorithm (DTGA) to solve it. They take advantage from both
276 temporal and spatial correlations between data sensed by different sensors, and
277 leverage prediction, to improve the lifetime. In \cite{xu2001geography}, Xu et
278 al. have described an algorithm, called Geographical Adaptive Fidelity (GAF),
279 which uses geographic location information to divide the area of interest into
280 fixed square grids. Within each grid, it keeps only one node staying awake to
281 take the responsibility of sensing and communication.
283 Some other approaches (outside the scope of our work) do not consider a
284 synchronized and predetermined time-slot where the sensors are active or not.
285 Indeed, each sensor maintains its own timer and its wake-up time is randomized
286 \cite{Ye03} or regulated \cite{cardei2005maximum} over time.
288 \section{MuDiLCO protocol description}
291 \subsection{Assumptions and primary points}
294 \textcolor{black}{The assumptions and the coverage model are identical to those presented
295 in~\cite{idrees2015distributed}. We consider a scenario in which sensors are deployed in high
296 density to initially ensure a high coverage ratio of the interested area. Each
297 sensor has a predefined sensing range $R_s$, an initial energy supply
298 (eventually different from each other) and is supposed to be equipped with
299 a module to locate its geographical positions. All space points within the
300 disk centered at the sensor with the radius of the sensing range are said to be
301 covered by this sensor.}
303 \indent Instead of working with the coverage area, we consider for each sensor a
304 set of points called primary points~\cite{idrees2014coverage}. We assume that
305 the sensing disk defined by a sensor is covered if all the primary points of
306 this sensor are covered. By knowing the position of wireless sensor node
307 (centered at the the position $\left(p_x,p_y\right)$) and its sensing range
308 $R_s$, we define up to 25 primary points $X_1$ to $X_{25}$ as described on
309 Figure~\ref{fig1}. The optimal number of primary points is investigated in
310 section~\ref{ch4:sec:04:06}.
312 The coordinates of the primary points are defined as follows:\\
313 %$(p_x,p_y)$ = point center of wireless sensor node\\
315 $X_2=( p_x + R_s * (1), p_y + R_s * (0) )$\\
316 $X_3=( p_x + R_s * (-1), p_y + R_s * (0)) $\\
317 $X_4=( p_x + R_s * (0), p_y + R_s * (1) )$\\
318 $X_5=( p_x + R_s * (0), p_y + R_s * (-1 )) $\\
319 $X_6=( p_x + R_s * (\frac{-\sqrt{2}}{2}), p_y + R_s * (\frac{\sqrt{2}}{2})) $\\
320 $X_7=( p_x + R_s * (\frac{\sqrt{2}}{2}), p_y + R_s * (\frac{\sqrt{2}}{2})) $\\
321 $X_8=( p_x + R_s * (\frac{-\sqrt{2}}{2}), p_y + R_s * (\frac{-\sqrt{2}}{2})) $\\
322 $X_9=( p_x + R_s * (\frac{\sqrt{2}}{2}), p_y + R_s * (\frac{-\sqrt{2}}{2})) $\\
323 $X_{10}= ( p_x + R_s * (\frac{-\sqrt{2}}{2}), p_y + R_s * (0)) $\\
324 $X_{11}=( p_x + R_s * (\frac{\sqrt{2}}{2}), p_y + R_s * (0))$\\
325 $X_{12}=( p_x + R_s * (0), p_y + R_s * (\frac{\sqrt{2}}{2})) $\\
326 $X_{13}=( p_x + R_s * (0), p_y + R_s * (\frac{-\sqrt{2}}{2})) $\\
327 $X_{14}=( p_x + R_s * (\frac{\sqrt{3}}{2}), p_y + R_s * (\frac{1}{2})) $\\
328 $X_{15}=( p_x + R_s * (\frac{-\sqrt{3}}{2}), p_y + R_s * (\frac{1}{2})) $\\
329 $X_{16}=( p_x + R_s * (\frac{\sqrt{3}}{2}), p_y + R_s * (\frac{- 1}{2})) $\\
330 $X_{17}=( p_x + R_s * (\frac{-\sqrt{3}}{2}), p_y + R_s * (\frac{- 1}{2})) $\\
331 $X_{18}=( p_x + R_s * (\frac{\sqrt{3}}{2}), p_y + R_s * (0)) $\\
332 $X_{19}=( p_x + R_s * (\frac{-\sqrt{3}}{2}), p_y + R_s * (0)) $\\
333 $X_{20}=( p_x + R_s * (0), p_y + R_s * (\frac{1}{2})) $\\
334 $X_{21}=( p_x + R_s * (0), p_y + R_s * (-\frac{1}{2})) $\\
335 $X_{22}=( p_x + R_s * (\frac{1}{2}), p_y + R_s * (\frac{\sqrt{3}}{2})) $\\
336 $X_{23}=( p_x + R_s * (\frac{- 1}{2}), p_y + R_s * (\frac{\sqrt{3}}{2})) $\\
337 $X_{24}=( p_x + R_s * (\frac{- 1}{2}), p_y + R_s * (\frac{-\sqrt{3}}{2})) $\\
338 $X_{25}=( p_x + R_s * (\frac{1}{2}), p_y + R_s * (\frac{-\sqrt{3}}{2})) $.
342 \includegraphics[scale=0.375]{fig26.pdf}
344 \caption{Wireless sensor node represented by up to 25~primary points}
347 \subsection{Background idea}
349 The WSN area of interest is, at first, divided into regular homogeneous
350 subregions using a divide-and-conquer algorithm. Then, our protocol will be
351 executed in a distributed way in each subregion simultaneously to schedule
352 nodes' activities for one sensing period. Sensor nodes are assumed to be
353 deployed almost uniformly and with high density over the region. The regular
354 subdivision is made so that the number of hops between any pairs of sensors
355 inside a subregion is less than or equal to 3.
357 As can be seen in Figure~\ref{fig2}, our protocol works in periods fashion,
358 where each period is divided into 4~phases: Information~Exchange,
359 Leader~Election, Decision, and Sensing. \textcolor{black}{Compared to
360 the DiLCO protocol described in~\cite{idrees2015distributed},} each sensing phase is itself
361 divided into $T$ rounds of equal duration and for each round a set of sensors (a
362 cover set) is responsible for the sensing task. In this way a multiround
363 optimization process is performed during each period after Information~Exchange
364 and Leader~Election phases, in order to produce $T$ cover sets that will take
365 the mission of sensing for $T$
366 rounds. \textcolor{black}{Algorithm~\ref{alg:MuDiLCO} is executed by each sensor
367 node~$s_j$ (with enough remaining energy) at the beginning of a period.}
369 \centering \includegraphics[width=125mm]{Modelgeneral.pdf} % 70mm
370 \caption{The MuDiLCO protocol scheme executed on each node}
374 \begin{algorithm}[h!]
376 \If{ $RE_j \geq E_{R}$ }{
377 \emph{$s_j.status$ = COMMUNICATION}\;
378 \emph{Send $INFO()$ packet to other nodes in the subregion}\;
379 \emph{Wait $INFO()$ packet from other nodes in the subregion}\;
381 \emph{LeaderID = Leader election}\;
382 \If{$ s_j.ID = LeaderID $}{
383 \emph{$s_j.status$ = COMPUTATION}\;
384 \emph{$\left\{\left(X_{1,k},\dots,X_{T,k}\right)\right\}_{k \in J}$ =
385 Execute Integer Program Algorithm($T,J$)}\;
386 \emph{$s_j.status$ = COMMUNICATION}\;
387 \emph{Send $ActiveSleep()$ packet to each node $k$ in subregion: a packet \\
388 with vector of activity scheduling $(X_{1,k},\dots,X_{T,k})$}\;
389 \emph{Update $RE_j $}\;
392 \emph{$s_j.status$ = LISTENING}\;
393 \emph{Wait $ActiveSleep()$ packet from the Leader}\;
394 \emph{Update $RE_j $}\;
397 \Else { Exclude $s_j$ from entering in the current sensing phase}
399 \caption{MuDiLCO($s_j$)}
403 \textcolor{black}{As already described in~\cite{idrees2015distributed}}, two
404 types of packets are used by the proposed protocol:
405 \begin{enumerate}[(a)]
406 \item INFO packet: such a packet will be sent by each sensor node to all the
407 nodes inside a subregion for information exchange.
408 \item Active-Sleep packet: sent by the leader to all the nodes inside a
409 subregion to inform them to remain Active or to go Sleep during the sensing
413 There are five status for each sensor node in the network:
414 \begin{enumerate}[(a)]
415 \item LISTENING: sensor node is waiting for a decision (to be active or not);
416 \item COMPUTATION: sensor node has been elected as leader and applies the
417 optimization process;
418 \item ACTIVE: sensor node is taking part in the monitoring of the area;
419 \item SLEEP: sensor node is turned off to save energy;
420 \item COMMUNICATION: sensor node is transmitting or receiving packet.
423 This protocol minimizes the impact of unexpected node failure (not due to
424 batteries running out of energy), because it works in periods. On the one hand,
425 if a node failure is detected before making the decision, the node will not
426 participate to this phase, and, on the other hand, if the node failure occurs
427 after the decision, the sensing task of the network will be temporarily
428 affected: only during the period of sensing until a new period starts. The
429 duration of the rounds is a predefined parameter. Round duration should be long
430 enough to hide the system control overhead and short enough to minimize the
431 negative effects in case of node failures.
433 The energy consumption and some other constraints can easily be taken into
434 account, since the sensors can update and then exchange their information
435 (including their residual energy) at the beginning of each period. However, the
436 pre-sensing phases (Information Exchange, Leader Election, and Decision) are
437 energy consuming for some nodes, even when they do not join the network to
440 At the beginning of each period, each sensor which has enough remaining energy
441 ($RE_j$) to be alive during at least one round ($E_{R}$ is the amount of energy
442 required to be alive during one round) sends (line 3 of
443 Algorithm~\ref{alg:MuDiLCO}) its position, remaining energy $RE_j$, and the
444 number of neighbors $NBR_j$ to all wireless sensor nodes in its subregion by
445 using an INFO packet (containing information on position coordinates, current
446 remaining energy, sensor node ID, number of its one-hop live neighbors) and then
447 waits for packets sent by other nodes (line 4).
449 After that, each node will have information about all the sensor nodes in the
450 subregion. The nodes in the same subregion will select (line 5) a Wireless
451 Sensor Node Leader (WSNL) based on the received information from all other nodes
452 in the same subregion. The selection criteria are, in order of importance:
453 larger number of neighbors, larger remaining energy, and then in case of
454 equality, larger index. Observations on previous simulations suggest to use the
455 number of one-hop neighbors as the primary criterion to reduce energy
456 consumption due to the communications.
458 %Each WSNL will solve an integer program to select which cover
459 % sets will be activated in the following sensing phase to cover the subregion
460 % to which it belongs. $T$ cover sets will be produced, one for each round. The
461 % WSNL will send an Active-Sleep packet to each sensor in the subregion based on
462 % the algorithm's results, indicating if the sensor should be active or not in
463 % each round of the sensing phase.
464 \subsection{Multiround Optimization model}
467 As shown in Algorithm~\ref{alg:MuDiLCO} at line 8, the leader (WNSL) will
468 execute an optimization algorithm based on an integer program to select the
469 cover sets to be activated in the following sensing phase to cover the subregion
470 to which it belongs. $T$ cover sets will be produced, one for each round. The
471 WSNL will send an Active-Sleep packet to each sensor in the subregion based on
472 the algorithm's results (line 10), indicating if the sensor should be active or
473 not in each round of the sensing phase.
475 The integer program is based on the model proposed by \cite{pedraza2006} with
476 some modifications, where the objective is to find a maximum number of disjoint
477 cover sets. To fulfill this goal, the authors proposed an integer program which
478 forces undercoverage and overcoverage of targets to become minimal at the same
479 time. They use binary variables $x_{jl}$ to indicate if sensor $j$ belongs to
480 cover set $l$. In our model, we consider binary variables $X_{t,j}$ to
481 determine the possibility of activating sensor $j$ during round $t$ of a given
482 sensing phase. We also consider primary points as targets. The set of primary
483 points is denoted by $P$ and the set of sensors by $J$. Only sensors able to be
484 alive during at least one round are involved in the integer program.
485 \textcolor{black}{Note that the proposed integer program is an
486 extension of the one formulated in~\cite{idrees2015distributed}, variables are now indexed in
487 addition with the number of round $t$.}
489 For a primary point $p$, let $\alpha_{j,p}$ denote the indicator function of
490 whether the point $p$ is covered, that is:
492 \alpha_{j,p} = \left \{
494 1 & \mbox{if the primary point $p$ is covered} \\
495 & \mbox{by sensor node $j$}, \\
496 0 & \mbox{otherwise.}\\
500 The number of active sensors that cover the primary point $p$ during
501 round $t$ is equal to $\sum_{j \in J} \alpha_{j,p} * X_{t,j}$ where:
505 1& \mbox{if sensor $j$ is active during round $t$,} \\
506 0 & \mbox{otherwise.}\\
510 We define the Overcoverage variable $\Theta_{t,p}$ as:
512 \Theta_{t,p} = \left \{
514 0 & \mbox{if the primary point $p$}\\
515 & \mbox{is not covered during round $t$,}\\
516 \left( \sum_{j \in J} \alpha_{jp} * X_{t,j} \right)- 1 & \mbox{otherwise.}\\
520 More precisely, $\Theta_{t,p}$ represents the number of active sensor nodes
521 minus one that cover the primary point $p$ during round $t$. The
522 Undercoverage variable $U_{t,p}$ of the primary point $p$ during round $t$ is
527 1 &\mbox{if the primary point $p$ is not covered during round $t$,} \\
528 0 & \mbox{otherwise.}\\
533 Our coverage optimization problem can then be formulated as follows:
535 \min \sum_{t=1}^{T} \sum_{p=1}^{|P|} \left(W_{\theta}* \Theta_{t,p} + W_{U} * U_{t,p} \right) \label{eq15}
540 \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
544 \sum_{t=1}^{T} X_{t,j} \leq \floor*{RE_{j}/E_{R}} \hspace{10 mm}\forall j \in J\hspace{6 mm}
549 X_{t,j} \in \lbrace0,1\rbrace, \hspace{10 mm} \forall j \in J, t = 1,\dots,T \label{eq17}
553 U_{t,p} \in \lbrace0,1\rbrace, \hspace{10 mm}\forall p \in P, t = 1,\dots,T \label{eq18}
557 \Theta_{t,p} \geq 0 \hspace{10 mm}\forall p \in P, t = 1,\dots,T \label{eq178}
561 \item $X_{t,j}$: indicates whether or not the sensor $j$ is actively sensing
562 during round $t$ (1 if yes and 0 if not);
563 \item $\Theta_{t,p}$ - {\it overcoverage}: the number of sensors minus one that
564 are covering the primary point $p$ during round $t$;
565 \item $U_{t,p}$ - {\it undercoverage}: indicates whether or not the primary
566 point $p$ is being covered during round $t$ (1 if not covered and 0 if
570 The first group of constraints indicates that some primary point $p$ should be
571 covered by at least one sensor and, if it is not always the case, overcoverage
572 and undercoverage variables help balancing the restriction equations by taking
573 positive values. The constraint given by equation~(\ref{eq144}) guarantees that
574 the sensor has enough energy ($RE_j$ corresponds to its remaining energy) to be
575 alive during the selected rounds knowing that $E_{R}$ is the amount of energy
576 required to be alive during one round.
578 There are two main objectives. First, we limit the overcoverage of primary
579 points in order to activate a minimum number of sensors. Second we prevent the
580 absence of monitoring on some parts of the subregion by minimizing the
581 undercoverage. The weights $W_\theta$ and $W_U$ must be properly chosen so as
582 to guarantee that the maximum number of points are covered during each round.
583 In our simulations, priority is given to the coverage by choosing $W_{U}$ very
584 large compared to $W_{\theta}$.
586 The size of the problem depends on the number of variables and constraints. The
587 number of variables is linked to the number of alive sensors $A \subseteq J$,
588 the number of rounds $T$, and the number of primary points $P$. Thus the
589 integer program contains $A*T$ variables of type $X_{t,j}$, $P*T$ overcoverage
590 variables and $P*T$ undercoverage variables. The number of constraints is equal
591 to $P*T$ (for constraints (\ref{eq16})) $+$ $A$ (for constraints (\ref{eq144})).
594 \section{Experimental framework}
597 \subsection{Simulation setup}
599 We conducted a series of simulations to evaluate the efficiency and the
600 relevance of our approach, using the discrete event simulator OMNeT++
601 \cite{varga}. The simulation parameters are summarized in Table~\ref{table3}.
602 Each experiment for a network is run over 25~different random topologies and the
603 results presented hereafter are the average of these 25 runs. We performed
604 simulations for five different densities varying from 50 to 250~nodes deployed
605 over a $50 \times 25~m^2 $ sensing field. More precisely, the deployment is
606 controlled at a coarse scale in order to ensure that the deployed nodes can
607 cover the sensing field with the given sensing range.
610 \caption{Relevant parameters for network initializing.}
614 Parameter & Value \\ [0.5ex]
616 Sensing field size & $(50 \times 25)~m^2 $ \\
617 Network size & 50, 100, 150, 200 and 250~nodes \\
618 Initial energy & 500-700~joules \\
619 Sensing time for one round & 60 Minutes \\
620 $E_{R}$ & 36 Joules\\
628 Our protocol is declined into four versions: MuDiLCO-1, MuDiLCO-3, MuDiLCO-5,
629 and MuDiLCO-7, corresponding respectively to $T=1,3,5,7$ ($T$ the number of
630 rounds in one sensing period). Since the time resolution may be prohibitive when
631 the size of the problem increases, a time limit threshold has been fixed when
632 solving large instances. In these cases, the solver returns the best solution
633 found, which is not necessary the optimal one. In practice, we only set time
634 limit values for $T=5$ and $T=7$. In fact, for $T=5$ we limited the time for
635 250~nodes, whereas for $T=7$ it was for the three largest network sizes.
636 Therefore we used the following values (in second): 0.03 for 250~nodes when
637 $T=5$, while for $T=7$ we chose 0.03, 0.06, and 0.08 for respectively 150, 200,
638 and 250~nodes. These time limit thresholds have been set empirically. The basic
639 idea is to consider the average execution time to solve the integer programs to
640 optimality for 100 nodes and then to adjust the time linearly according to the
641 increasing network size. After that, this threshold value is increased if
642 necessary so that the solver is able to deliver a feasible solution within the
643 time limit. In fact, selecting the optimal values for the time limits will be
644 investigated in the future.
646 In the following, we will make comparisons with two other methods. The first
647 method, called DESK and proposed by \cite{ChinhVu}, is a fully distributed
648 coverage algorithm. The second method, called GAF~\cite{xu2001geography},
649 consists in dividing the region into fixed squares. During the decision phase,
650 in each square, one sensor is then chosen to remain active during the sensing
653 Some preliminary experiments were performed to study the choice of the number of
654 subregions which subdivides the sensing field, considering different network
655 sizes. They show that as the number of subregions increases, so does the network
656 lifetime. Moreover, it makes the MuDiLCO protocol more robust against random
657 network disconnection due to node failures. However, too many subdivisions
658 reduce the advantage of the optimization. In fact, there is a balance between
659 the benefit from the optimization and the execution time needed to solve it. In
660 the following we have set the number of subregions to~16 \textcolor{black}{as
661 recommended in~\cite{idrees2015distributed}}.
663 \subsection{Energy model}
664 \textcolor{black}{The energy consumption model is detailed
665 in~\cite{raghunathan2002energy}. It is based on the model proposed
666 by~\cite{ChinhVu}. We refer to the sensor node Medusa~II which uses an Atmels
667 AVR ATmega103L microcontroller~\cite{raghunathan2002energy} to use numerical
672 \textcolor{black}{To evaluate our approach we consider the performance metrics
673 detailed in~\cite{idrees2015distributed}, which are: Coverage Ratio, Network
674 Lifetime and Energy Consumption. Compared to the previous definitions,
675 formulations of Coverage Ratio and Energy Consumption are enriched with the
680 \item {{\bf Coverage Ratio (CR)}:} the coverage ratio measures how much of the
681 area of a sensor field is covered. In our case, the sensing field is
682 represented as a connected grid of points and we use each grid point as a
683 sample point to compute the coverage. The coverage ratio can be calculated by:
686 \mbox{CR}(\%) = \frac{\mbox{$n^t$}}{\mbox{$N$}} \times 100,
688 where $n^t$ is the number of covered grid points by the active sensors of all
689 subregions during round $t$ in the current sensing phase and $N$ is the total
690 number of grid points in the sensing field of the network. In our simulations $N
691 = 51 \times 26 = 1326$ grid points.
693 \item{{\bf Number of Active Sensors Ratio (ASR)}:} it is important to have as
694 few active nodes as possible in each round, in order to minimize the
695 communication overhead and maximize the network lifetime. The Active Sensors
696 Ratio is defined as follows:
698 \scriptsize \mbox{ASR}(\%) = \frac{\sum\limits_{r=1}^R
699 \mbox{$A_r^t$}}{\mbox{$|J|$}} \times 100,
701 where $A_r^t$ is the number of active sensors in the subregion $r$ during round
702 $t$ in the current sensing phase, $|J|$ is the total number of sensors in the
703 network, and $R$ is the total number of subregions in the network.
705 \item {{\bf Network Lifetime}:} we define the network lifetime as the time until
706 the coverage ratio drops below a predefined threshold. We denote by
707 $Lifetime_{95}$ (respectively $Lifetime_{50}$) the amount of time during which
708 the network can satisfy an area coverage greater than $95\%$ (respectively
709 $50\%$). We assume that the network is alive until all nodes have been drained
710 of their energy or the sensor network becomes disconnected. Network
711 connectivity is important because an active sensor node without connectivity
712 towards a base station cannot transmit information on an event in the area
715 \item {{\bf Energy Consumption (EC)}:} the average energy consumption can be
716 seen as the total energy consumed by the sensors during the $Lifetime_{95}$ or
717 $Lifetime_{50}$ divided by the number of rounds. EC can be computed as
722 \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},
725 where $M$ is the number of periods and $T_m$ the number of rounds in a
726 period~$m$, both during $Lifetime_{95}$ or $Lifetime_{50}$. The total energy
727 consumed by the sensors (EC) comes through taking into consideration four main
728 energy factors. The first one , denoted $E^{\scriptsize \mbox{com}}_m$,
729 represents the energy consumption spent by all the nodes for wireless
730 communications during period $m$. $E^{\scriptsize \mbox{list}}_m$, the next
731 factor, corresponds to the energy consumed by the sensors in LISTENING status
732 before receiving the decision to go active or sleep in period $m$.
733 $E^{\scriptsize \mbox{comp}}_m$ refers to the energy needed by all the leader
734 nodes to solve the integer program during a period. Finally, $E^a_t$ and $E^s_t$
735 indicate the energy consumed by the whole network in round $t$.
737 %\item {Network Lifetime:} we have defined the network lifetime as the time until all
738 %nodes have been drained of their energy or each sensor network monitoring an area has become disconnected.
743 \section{Experimental results and analysis}
746 \subsection{Performance analysis for different number of primary points}
747 \label{ch4:sec:04:06}
749 In this section, we study the performance of MuDiLCO-1 approach (with only one
750 round as in~\cite{idrees2015distributed}) for different numbers of primary
751 points. The objective of this comparison is to select the suitable number of
752 primary points to be used by a MuDiLCO protocol. In this comparison, MuDiLCO-1
753 protocol is used with five primary point models, each model corresponding to a
754 number of primary points, which are called Model-5 (it uses 5 primary points),
755 Model-9, Model-13, Model-17, and Model-21. \textcolor{black}{Note
757 presented in~\cite{idrees2015distributed} correspond to Model-13 (13 primary
760 \subsubsection{Coverage ratio}
762 Figure~\ref{Figures/ch4/R2/CR} shows the average coverage ratio for 150 deployed
763 nodes. As can be seen, at the beginning the models which use a larger number of
764 primary points provide slightly better coverage ratios, but latter they are the
765 worst. Moreover, when the number of periods increases, the coverage ratio
766 produced by all models decrease due to dead nodes. However, Model-5 is the one
767 with the slowest decrease due to lower numbers of active sensors in the earlier
768 periods. Overall this model is slightly more efficient than the other ones,
769 because it offers a good coverage ratio for a larger number of periods.
773 \includegraphics[scale=0.5] {R2CR.pdf}
774 \caption{Coverage ratio for 150 deployed nodes}
775 \label{Figures/ch4/R2/CR}
778 \subsubsection{Network lifetime}
780 Finally, we study the effect of increasing the number of primary points on the
781 lifetime of the network. As highlighted by Figures~\ref{Figures/ch4/R2/LT}(a)
782 and \ref{Figures/ch4/R2/LT}(b), the network lifetime obviously increases when
783 the size of the network increases, with Model-5 which leads to the largest
784 lifetime improvement.
789 \includegraphics[scale=0.5]{R2LT95.pdf}\\~ ~ ~ ~ ~(a) \\
791 \includegraphics[scale=0.5]{R2LT50.pdf}\\~ ~ ~ ~ ~(b)
793 \caption{Network lifetime for (a) $Lifetime_{95}$ and (b) $Lifetime_{50}$}
794 \label{Figures/ch4/R2/LT}
797 Comparison shows that Model-5, which uses less number of primary points, is the
798 best one because it is less energy consuming during the network lifetime. It is
799 also the better one from the point of view of coverage ratio, as stated
800 before. Therefore, we have chosen the model with five primary points for all the
801 experiments presented thereafter.
803 \subsection{Coverage ratio}
805 Figure~\ref{fig3} shows the average coverage ratio for 150 deployed nodes. We
806 can notice that for the first 30~rounds both DESK and GAF provide a coverage
807 which is a little bit better than the one of MuDiLCO. This is due to the fact
808 that, in comparison with MuDiLCO which uses optimization to put in SLEEP status
809 redundant sensors, more sensor nodes remain active with DESK and GAF. As a
810 consequence, when the number of rounds increases, a larger number of node
811 failures can be observed in DESK and GAF, resulting in a faster decrease of the
812 coverage ratio. Furthermore, our protocol allows to maintain a coverage ratio
813 greater than 50\% for far more rounds. Overall, the proposed sensor activity
814 scheduling based on optimization in MuDiLCO maintains higher coverage ratios of
815 the area of interest for a larger number of rounds. It also means that MuDiLCO
816 saves more energy, with less dead nodes, at most for several rounds, and thus
817 should extend the network lifetime. MuDiLCO-7 seems to have most of the time
818 the best coverage ratio up to round~80, after that MuDiLCO-5 is slightly better.
822 \includegraphics[scale=0.5] {FCR.pdf}
823 \caption{Average coverage ratio for 150 deployed nodes}
827 \subsection{Active sensors ratio}
829 It is crucial to have as few active nodes as possible in each round, in order to
830 minimize the communication overhead and maximize the network
831 lifetime. Figure~\ref{fig4} presents the active sensor ratio for 150 deployed
832 nodes all along the network lifetime. It appears that up to round thirteen, DESK
833 and GAF have respectively 37.6\% and 44.8\% of nodes in ACTIVE status, whereas
834 MuDiLCO clearly outperforms them with only 24.8\% of active nodes. Obviously,
835 in that case DESK and GAF have less active nodes, since they have activated many
836 nodes at the beginning. Anyway, MuDiLCO activates the available nodes in a more
841 \includegraphics[scale=0.5]{FASR.pdf}
842 \caption{Active sensors ratio for 150 deployed nodes}
846 \subsection{Stopped simulation runs}
848 A simulation ends when the sensor network becomes disconnected (some nodes are
849 dead and are not able to send information to the base station). We report the
850 number of simulations that are stopped due to network disconnections and for
851 which round it occurs. Figure~\ref{fig6} reports the cumulative percentage of
852 stopped simulations runs per round for 150 deployed nodes. This figure gives
853 the break point for each method. DESK stops first, after approximately
854 45~rounds, because it consumes the more energy by turning on a large number of
855 redundant nodes during the sensing phase. GAF stops secondly for the same reason
856 than DESK. Let us emphasize that the simulation continues as long as a network
857 in a subregion is still connected.
861 \includegraphics[scale=0.5]{FSR.pdf}
862 \caption{Cumulative percentage of stopped simulation runs for 150 deployed nodes}
866 \subsection{Energy consumption} \label{subsec:EC}
868 We measure the energy consumed by the sensors during the communication,
869 listening, computation, active, and sleep status for different network densities
870 and compare it with the two other methods. Figures~\ref{fig7}(a)
871 and~\ref{fig7}(b) illustrate the energy consumption, considering different
872 network sizes, for $Lifetime_{95}$ and $Lifetime_{50}$.
877 \parbox{9.5cm}{\includegraphics[scale=0.5]{FEC95.pdf}} & (a) \\
879 \parbox{9.5cm}{\includegraphics[scale=0.5]{FEC50.pdf}} & (b)
881 \caption{Energy consumption for (a) $Lifetime_{95}$ and
886 The results show that MuDiLCO is the most competitive from the energy
887 consumption point of view. The other approaches have a high energy consumption
888 due to activating a larger number of redundant nodes as well as the energy
889 consumed during the different status of the sensor node.
891 Energy consumption increases with the size of the networks and the number of
892 rounds. The curve Unlimited-MuDiLCO-7 shows that energy consumption due to the
893 time spent to optimally solve the integer program increases drastically with the
894 size of the network. When the resolution time is limited for large network
895 sizes, the energy consumption remains of the same order whatever the MuDiLCO
896 version. As can be seen with MuDiLCO-7.
898 \subsection{Execution time}
901 We observe the impact of the network size and of the number of rounds on the
902 computation time. Figure~\ref{fig77} gives the average execution times in
903 seconds (needed to solve the optimization problem) for different values of
904 $T$. The modeling language for Mathematical Programming (AMPL)~\cite{AMPL} is
905 employed to generate the Mixed Integer Linear Program instance in a standard
906 format, which is then read and solved by the optimization solver GLPK (GNU
907 linear Programming Kit available in the public domain) \cite{glpk} through a
908 Branch-and-Bound method. The original execution time is computed on a laptop
909 DELL with Intel Core~i3~2370~M (2.4 GHz) processor (2 cores) and the MIPS
910 (Million Instructions Per Second) rate equal to 35330. To be consistent with the
911 use of a sensor node with Atmels AVR ATmega103L microcontroller (6 MHz) and a
912 MIPS rate equal to 6 to run the optimization resolution, this time is multiplied
913 by 2944.2 $\left( \frac{35330}{2} \times \frac{1}{6} \right)$ and reported on
914 Figure~\ref{fig77} for different network sizes.
918 \includegraphics[scale=0.5]{FT.pdf}
919 \caption{Execution Time (in seconds)}
923 As expected, the execution time increases with the number of rounds $T$ taken
924 into account to schedule the sensing phase. Obviously, the number of variables
925 and constraints of the integer program increases with $T$, as explained in
926 section~\ref{mom}, the times obtained for $T=1,3$ or $5$ seem bearable. But for
927 $T=7$, without any limitation of the time, they become quickly unsuitable for a
928 sensor node, especially when the sensor network size increases as demonstrated
929 by Unlimited-MuDiLCO-7. Notice that for 250 nodes, we also limited the
930 execution time for $T=5$, otherwise the execution time, denoted by
931 Unlimited-MuDiLCO-5, is also above MuDiLCO-7. On the one hand, a large value
932 for $T$ permits to reduce the energy-overhead due to the three pre-sensing
933 phases, on the other hand a leader node may waste a considerable amount of
934 energy to solve the optimization problem. Thus, limiting the time resolution for
935 large instances allows to reduce the energy consumption without any impact on
936 the coverage quality.
938 \subsection{Network lifetime}
940 The next two figures, Figures~\ref{fig8}(a) and \ref{fig8}(b), illustrate the
941 network lifetime for different network sizes, respectively for $Lifetime_{95}$
942 and $Lifetime_{50}$. Both figures show that the network lifetime increases
943 together with the number of sensor nodes, whatever the protocol, thanks to the
944 node density which results in more and more redundant nodes that can be
945 deactivated and thus save energy. Compared to the other approaches, our MuDiLCO
946 protocol maximizes the lifetime of the network. In particular the gain in
947 lifetime for a coverage over 95\%, and a network of 250~nodes, is greater than
948 43\% when switching from GAF to MuDiLCO-5.
949 %The lower performance that can be observed for MuDiLCO-7 in case
950 %of $Lifetime_{95}$ with large wireless sensor networks results from the
951 %difficulty of the optimization problem to be solved by the integer program.
952 %This point was already noticed in subsection \ref{subsec:EC} devoted to the
953 %energy consumption, since network lifetime and energy consumption are directly
955 Overall, it clearly appears that computing a scheduling for several rounds is
956 possible and relevant, providing that the execution time to solve the
957 optimization problem for large instances is limited. Notice that rather than
958 limiting the execution time, similar results might be obtained by replacing the
959 computation of the exact solution with the finding of a suboptimal one using a
960 heuristic approach. For our simulation setup and considering the different
961 metrics, MuDiLCO-5 seems to be the best suited method compared to MuDiLCO-7.
966 \parbox{9.5cm}{\includegraphics[scale=0.5125]{FLT95.pdf}} & (a) \\
968 \parbox{9.5cm}{\includegraphics[scale=0.5125]{FLT50.pdf}} & (b)
970 \caption{Network lifetime for (a) $Lifetime_{95}$ and
975 \section{Conclusion and future works}
976 \label{sec:conclusion}
978 We have addressed the problem of the coverage and of the lifetime optimization
979 in wireless sensor networks. This is a key issue as sensor nodes have limited
980 resources in terms of memory, energy, and computational power. To cope with this
981 problem, the field of sensing is divided into smaller subregions using the
982 concept of divide-and-conquer method, and then we propose a protocol which
983 optimizes coverage and lifetime performances in each subregion. Our protocol,
984 called MuDiLCO (Multiround Distributed Lifetime Coverage Optimization) combines
985 two efficient techniques: network leader election and sensor activity
986 scheduling. The activity scheduling in each subregion works in periods, where
987 each period consists of four phases: (i) Information Exchange, (ii) Leader
988 Election, (iii) Decision Phase to plan the activity of the sensors over $T$
989 rounds, (iv) Sensing Phase itself divided into $T$ rounds.
991 Simulations results show the relevance of the proposed protocol in terms of
992 lifetime, coverage ratio, active sensors ratio, energy consumption, execution
993 time. Indeed, when dealing with large wireless sensor networks, a distributed
994 approach, like the one we propose, allows to reduce the difficulty of a single
995 global optimization problem by partitioning it in many smaller problems, one per
996 subregion, that can be solved more easily. Furthermore, results also show that
997 to plan the activity of sensors for large network sizes, an approach to obtain a
998 near optimal solution is needed. Indeed, an exact resolution of the resulting
999 optimization problem leads to prohibitive computation times and thus to an
1000 excessive energy consumption.
1002 %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
1003 %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.
1004 % use section* for acknowledgement
1006 \section*{Acknowledgment}
1007 This work is partially funded by the Labex ACTION program (contract
1008 ANR-11-LABX-01-01). Ali Kadhum IDREES would like to gratefully acknowledge the
1009 University of Babylon - Iraq for the financial support and Campus France (The
1010 French national agency for the promotion of higher education, international
1011 student services, and international mobility) for the support received when he
1012 was Ph.D. student in France.
1013 %, and the University ofFranche-Comt\'e - France for all the support in France.
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