School of Computer Science and Technology, University of Science and Technology of China, Hefei, China
Email: ammar12@mail.ustc.edu.cn
Copyright ? 2013 Ammar Hawbani et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Received November 6, 2013; revised December 6, 2013; accepted December 13, 2013
Keywords: Sensors Groups; WSN; Sub-Group; Sensors Organize
ABSTRACT
The grouping of sensors is a calculation method for partitioning the wireless sensor network into groups, each group consisting of a collection of sensors. A sensor can be an element of multiple groups. In the present paper, we will show a model to divide the wireless sensor network sensors into groups. These groups could communicate and work together in a cooperative way in order to save the time of routing and energy of WSN. In addition, we will present a way to show how to organize the sensors in groups and provide a combinatorial analysis of some issues related to the performance of the network.
1. Introduction
A wireless sensor network consists of spatially distributed autonomous sensors to monitor physical or environmental conditions, such as temperature, sound, pressure, etc. [1-5]. The sensors cooperate with each other to monitor the targets and send the collected information to the base station [6-8]. Sensors are battery-powered devices having a limited lifetime, restricted sensing range, and narrow communication range [9-11], and densely deployed in harsh environment [12-15]. Organization of sensors in the form of groups is very important, which would facilitate transferring data and routing from one group to another, and it also offers an easy way to analyze the WSN problems such as coverage, localization, connectivity, tracing and data routing [16-20].
2. Sensors Grouping Strategy
A Group of sensors is a collection of overlapped sensors in a single area. Let us define the degree of overloaded sensors by the maximum number of sensors overlapped in the same area, here we denote to the maximum coverage degree of an area by
where where
is an area notation called r,
are the overlapped sensors, and
the number of overlapped sensors. The overlapped
sensors that create a degree of an area
Create a group of sensors denoted by
we call
the coverage degree. Figure 1 shows four groups
, and
. The maximum degree of sensor
and senor
is
that occurs in the area of intersection, which
means that there is one and only one area covered by two sensors and that is the
maximal overlapping that could be produced, so sensor
and
create a group of two sensors denoted by
. Sake of convenience, we denote to the group of sensors
that build up the WSN by
which we call it the mother network group or simply the
mother group.
2.1. Counting the Sub-Areas of Sensors Group
Here we start by asking, how many sub-areas are generated if unit disk sensors are partially overlapped?
Assuming there is no fully overlapping between sensors, and all sensors are
homogenous (sensors have the same sensing range). Say
is the function to count the number of sub-areas,
definitely
.
,
,
,
(seeFigure 2). What
is
?
.
Theorem 1: the sub-areas number of a sensors group
(a)
(b)
Figure 1. Partitioning the WSN into group.
is
(1)
Proof: suppose we have a group of sensors as shown in Figure
3, we can see that the number of areas inside each sensor’s range is
seven. Using Top-down approach from
to
, the number of areas for the top sensor
is seven (red areas namely 1, 2, 3, 4, 5, 6, 7).
The number of areas inside the sensor’s range
are seven, namely (4, 5, 6, 7, 8, 9 10), but the
red colored areas, 2, 3, 4, 5, already counted in
, so there are only 3 blue colored areas inside sensor’s
range
, namely 8, 9, 10. For the sensor
, it has seven areas inside its sensing range, the 3, 5,
6, 7 are red areas already counted in sensor’s range
, the area 10 is blue area already counted in sensor’s
range
, thus still two black areas in sensor’s range
, namely 11, 12. For sensing range of
, there are seven areas inside it, three are red areas
(4, 5, 6), two are blue areas (9, 10), and one area is black (11), so there is
still one area only in
(13). Therefore, the number of areas from top to
down is 7 + 3 + 2 + 1 = 13. Generally, counting the sub-areas from top to down,
the top sensor contains
areas, the second sensor inside the group
Figure 2. (a) the
number of sub-areas of (b) the number of sub-areas of
(c) the number of sub-areas of
(d) the number of sub-areas of
.
Figure 3. The 13 areas
of group.
contains areas, the third sensor contains
areas… the last sensor contains one area
. Totally, there are
of areas. Generally, there count of areas is
In addition, we can proof theorem 1 by counting the areas of a group basing
on the degree of coverage, if an area covered by k sensors then it called
k-covered area. For a group there is only one area is k-covered (the maximum
degree of coverage), in the remainder areas, there are k areas are1-covered, k
areas are 2-coverd, k areas are 3-coverd… k areas are k-1 covered. Let
be the number of areas that j-covered inside a group of
sensors
. For example,
means, there are five areas 1-coverd in
. In Figure 4(a),
the group of sensors
, the number of 1-coverd areas is five. We can count the
sum of areas of sensors group
as below:
Lemma 1: for sensor range belongs to a group, there are only one area k-covered, k area 1-coverd, k
areas are 2-coverd, k areas are 3-coverd… and k areas k-1 covered.
Lemma 2: for a group, all sensors have the same characteristics, for example,
the number of areas, the degree of coverage for each area, the number of
intersection points located on the border of the sensor, and the number of
intersection points located inside sensor’s range.
2.2. Counting the Intersection Points of a Sensors Group
Counting the intersection points of k-overlapped sensors is an easy
combination problem. Before proving, here we denote to the number of
intersection points by, clearly
,
,
,
,
,
… then what is the
?
Theorem 2: the number of intersection points of sensors group is
(2)
Proof: Assuming that there are k sensors and each sensor has two intersection
points with each neighbor sensor, since each sensor has intersection points with others, applying this
method to all sensors, we get the total amount of intersection points as
. However, while calculating, every single point has been
repeatedly counted twice, thus the right answer in regards to the intersection
points quantity should be
.
We can use top down approach to calculate the number of intersection points,
as shown in theFigure 5(a).
is the top sensor;
is the bottom sensor of the group. The number of
intersection points inside (internal) and on the border of sensing range of the
top sensor
is
. In the second node
, there are k-2 of intersection points. In the third
node
, there are k-3 of intersection points. In the fourth
node
, there are k-4 of intersection points, and there is 0
intersection points in the bottom sensor.
Totally the number of intersection points is
Another method to count the intersection points of a group, we can imagine
that the number of intersection points as the number of 2-permutation of k
sensors, for example, S is a set of overlapped sensors . The 2-permutation of S is:
,
We can use the Recurrence relation to find the number of intersection points of a group of sensors. We can find the recurrence relation of the number of intersection points as below:
(3)
which can be easily solved using generation function [21]. (See the proof of
theorem 3), the solution is , so
.
2.3. Counting the Number of Intersection Points That Located within the Sensing Rang of a Sensor Associated to a Group (Internal Points and External Points)
In Figure 5(c), we can see that when k = 3 the number of intersection points located in the black sensor are 5, in Figure 5(b) k = 4, the number of intersection points located in the red sensor are 9, when k = 5 the number of intersection points are 14.
Theorem 3: for a group of sensors, the number of intersection points within the sensing
range of sensor is
Proof: it is easy to realize that the number of intersection points (internal and external) of the sensor is satisfying the recursive relation:
(4)
(a)
(b)
Figure 4. (a) group of sensors, (b)
group of sensors.
(a)
(b)
(c)
Figure 5. (a)
Intersection points of group, (b) intersection points of group
, (c) intersection points of group
.
So finding the solution to this recursive relation is the proof of the theorem.
Suppose the generation function is
In addition, suppose that
Then
The external intersection points of sensors are the points located on the border of a sensor. However, the internal points are those points located inside the sensors but not on the border.
Lemma 3 (the number of external points): the number of intersection points
located on the border of a sensor, which belongs to a group of sensors is
.
Proof: from Figure 5, it is easy to realize that the number of intersection points (external) of the sensor is satisfying the recursive relation:
We can solve this relation using generation function as in the proof of theorem 3. Therefore, the solution to this recursive relation is the proof of this theorem
.
Lemma 4 (the number of internal points): the number of intersection points located inside a sensor (not including the points located on the border) is
Proof: from Figure 5, it is easy to realize that the number of intersection points (internal) of the sensor is satisfying the recursive relation:
(5)
We can solve this relation using generation function as in the proof of theorem 3. Therefore, the solution to this recursive relation is the proof of this theorem.
From lemma 3, and lemma 4, we get the number of intersection points of a
sensor that belongs to a group of sensors by counting the intersection points located on the
border of the sensor (external points) and the intersection points located
inside the sensor (internal points).
(6)
2.4. Counting the Number of Areas within the Sensing Range
of a Sensor That Belongs to a Group
Theorem 4: The number of areas inside the sensor that belongs to a group of sensors
is
Proof: it is easy to realize that the number of areas inside the sensor is satisfying the recursive relation:
(7)
We can solve this relation using generation function as in the proof of theorem 3. Therefore, the solution to this recursive relation is the proof of this theorem
2.5. Counting the Number of Areas Located within the Sensing Range of a Sensor That Belongs to Multiple Groups
In Figure 1, the network sensors group is:
Our goal is to count the number of areas inside the sensor that associated to multiple groups. The groups to
which
belongs can be defined as following:
Say that then we can define the mother group of
as:
.
, where a, b, c are the positive integers numbers that
represent the degree of coverage.
As shown in Figure 1 we can define
the mother group of sensors,
,
,
,
,
and
as below:
Since only, then the mother group of sensor
is
Since, then the mother group of sensor
is
Since, then the mother group of sensor
is
Since, then the mother group of sensor
is
Since, then the mother group of sensor
is
Since, then the mother group of sensor
is
Since, then the mother group of sensor
is
It is clearly that the mother group of sensors of the whole network is equal to the union of mother groups of all sensors as shown below:
Let us now count the number of areas inside a sensor; these areas are
generated by intersection of multiple groups of sensors. For facilitate, let us
define as the number of areas inside a sensor
, which are generated by overlapping of a group of
sensors
. As explained above, the mother group of
is
, according to theorem the number of areas which created
inside
is
(indicated in Figure 6 by numbers 1, 2, 3, 4. The
number of areas which are created inside,
, is
.
The total number of areas inside a sensor, which, associated to multiple groups is denoted by
. these areas are created by intersection of sensors
belong the mother groups
.form the first glance, the
seems like
However, this form is not correct, because is an element belongs to every sup-group
of
this means that there is one area will be
counted
times. Let us denote the length of mother group
by
which indicates the number of sub-groups inside the
mother group of the sensor. So the corrected count of areas inside
, which belongs to
, is:
(9)
Below we can count the number of areas of sensors of Figure 7
2.6. Number of Distributed Messages
One of our aims is to find the number of distributed messages that will be
generated during communications of sensor associated to mother group
. Let us define the number of messages by
.For ease, let
be the order of
.
Indicates the number of sensors that belong to
every sub-group inside the mother group
, but not including
, with no repetition, (some sensors might belong to more
than one sub-group). For example Figure 1,
the order of
is
; the order of
is
Figure 6. The number of
areas inside sensor by group of sensors
.
Figure 7. Example of groups of sensors.
To generalize this idea, we can write the equation further. We have associated to the mother group
, the order of mother group of
is as the equation below
Here the integer number is the count of subgroups of
. In addition, c is the repetition.
It is clear that since the degree of sub-group
is one and the there is only one sub-group.
Applying this calculation to mother group of sensor
, the order
.
Theorem 4: The number of distributed messages sent form, associated to a mother group
, is
Proof: The number of messages depends on the degree of overlapped sensors.
The more the degrees of coverage are, the more the areas will be generated.
Therefore, the more messages will be generated. When a target moves within the
range of a sensor, it will send notification messages to all neighbors but
certainly not to itself. Since the sensor contains a certain number of
intersection areas and a certain number of sensors cover these areas, the sensor
will send a notification message to all the sensors that cover the same
area.
is the number of areas inside
which belongs to
, and
is the order of
, then
.
The number of messages of the network in Figure 1
3. Conclusion
We had introduced a new method of organizing the sensors of WSN into groups, which would be easy to manage and communicate. This new idea could be applied in coverage algorithms in order to control one node and one target at any given moment, and it could be used to speed up the routing algorithms as well.
4. Acknowledgements
The authors would like to acknowledge The National Natural Science Foundation of China, the National Science Technology Major Project and the China Scholarship Councilfor their supports.
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Distributed messages of network shown in Figure 1.
NOTES
*This paper is supported by The National Natural Science Foundation of China (NO.61272472, 61232018, 61202404) and the National Science Technology Major Project (NO. 2012ZX10004301-609).
Sensors Grouping Model for Wireless Sensor Network*,布布扣,bubuko.com