Life Time Sensitive Weighted Clustering on Wireless Sensor

Networks

Elnaz Alizadeh Jarchlo

and Cüneyt F. Bazlamaçcı

Department of Information Systems, Informatics Institute, Middle East Technical University, 06800, Ankara, Turkey

Department of Electrical and Electronics Engineering, Middle East Technical University, 06800, Ankara, Turkey

Keywords: Wireless Sensor Networks, Network Lifetime, Clustering.

Abstract: The present paper considers weighted clustering algorithms for mobile ad hoc networks (MANET) and

wireless sensor networks (WSN). First, we summarize the similarities and differences between the two

types of networks as then examine the existing weighted clustering algorithms proposed so far. We

specifically examine the objective functions and performances of the algorithm in terms of various

parameters. In addition, we proposed a new algorithm called as the Life Time Sensitive Weighted

Clustering Algorithm (LTS-WCA), which aims to adapt the already existing weighted clustering algorithm

(WCA) proposed for MANET to WSN and modify and enhance it. WCA was proposed in the literature for

forming cluster-heads in mobile ad hoc networks but we have demonstrated that it can also be effective

when used in a wireless sensor network domain.

1 INTRODUCTION

Sensor networks include a large number of sensors,

which are able to sense the environment and process

data in order to transfer gathered information to the

sink(s). Wireless sensor nodes started to play critical

roles in our lives. Many researchers have attempted

to utilize the existing theoretical studies in order to

apply them on practical applications in various areas

such as medicine (e.g. health monitoring (Li, et.al.

2009)), environment (e.g. disaster monitoring),

military (e.g. target surveillance and battlefield

mapping (Dechene, et.al. 2008)) and agriculture

(Burrell, et.al., 2004), etc.

Clustering a network leads to a creating a

hierarchical one by partitioning the existing flat

network into several groups of nodes, where each

group has a leader node called ‘cluster-head’ and the

remaining local nodes, which are connected to their

associated cluster-heads, are called ‘cluster

members’. The cluster-heads then are usually

connected in the shape of a backbone of the

corresponding network. One of the main issues in a

clustering algorithm is the process of categorizing

the nodes into disjoint groups and choosing the most

appropriate nodes as cluster-heads for having an

efficient network. There are different types of

clustering algorithms running on mobile ad hoc

networks (MANET) and wireless sensor networks

(WSN).

The present work aims at modifying and

enhancing the weighted clustering algorithm

(WCA), which was frequently cited for the purpose

of forming cluster-heads in mobile ad hoc networks.

The main argument for choosing it as the subject of

this study is its potential effectiveness when used in

a wireless sensor network domain.

The paper concentrates on the issue of energy

efficiency in clustering in WSN and especially on

increasing the network life time by considering

several critical parameters in this new algorithm

called as the Life-Time Sensitive Weighted

Clustering Algorithm (LTS-WCA).

Section 2 describes MANET and WSN and

briefly overviews the existing weighted clustering

approaches proposed for them. Section 3 presents

our new method, called as Life-Time Sensitive

Clustering Algorithm (LTS-WCA) while

emphasizing the differences between this proposal

and its original version called as Weighted

Clustering Algorithm (WCA). Section 4 includes our

implementation of the algorithm, the simulation

study carried out on LTS-WCA using ns2 simulator,

and evaluation results. Finally, section 5 concludes

the paper.

Alizadeh Jarchlo E. and Bazlamaçcı C..

Life Time Sensitive Weighted Clustering on Wireless Sensor Networks.

DOI: 10.5220/0004730700410051

In Proceedings of the 3rd International Conference on Sensor Networks (SENSORNETS-2014), pages 41-51

ISBN: 978-989-758-001-7

 2014 SCITEPRESS (Science and Technology Publications, Lda.)

2 MANET VS WSN

Mobile ad hoc networks and wireless sensor

networks have both similarities and differences. The

main similarities between MANET and WSN are

described as follows (Jindal, et.al., 2011), (MANET

vs WSN):

• Both are distributed and self-organized networks

without any central infrastructure.

• Both use wireless links for communication

purposes.

• Communication and routing among nodes may be

in multi hop fashion.

The main differences between MANET and

WSN can be listed as follows (MANET vs WSN):

• MANET users are generally appliances designed

for human beings (e.g. laptop, computers, PDAs,

mobile radio terminals, etc.) but WSNs focus

mostly on interactions with the environment

(monitoring and sensing the environment or maybe

tracking objects and/or activities in the sensing

environment).

• MANET network density is smaller in comparison

with WSN and the number of WSN sensor nodes

is higher in comparison with MANET.

• The number of active users in the deployment area

specifies the network size in MANET, however the

extension of the observed area, characteristics of

the nodes and the required redundancy level define

the number of nodes in WSN.

• Data traffic in MANET is higher than WSN

because of using services like web, mail, video,

etc.

• Sensor nodes in MANET are powerful

computation devices however in WSN they are

cheap tiny nodes.

• Energy concerns in MANET are of secondary

importance in comparison to WSN. Stored energy

in tiny sensor nodes in WSN is very restricted and

the quick loss of energy is considered as a main

problem in WSN.

The purposes of running clustering algorithms

on these two types of networks are slightly different.

Wireless sensor networks mostly concentrate on

how to sense the environment and send the gathered

data to sink(s) aiming to increase the network life

time and energy efficiency but in mobile ad hoc

networks the main goal is to distribute the generated

traffic among nodes by routing it in a multi hop

fashion.

Weighted Clustering Algorithm (WCA) is one of

the clustering algorithms, which was originally and

initially applied on mobile ad hoc networks. It

considers several different parameters in order to

select a cluster-head (CH) while running the

algorithm. We believe it to be more beneficial

compared to other clustering algorithms that take

one or two parameters into account at most. The

main objectives of applying WCA on MANET are

choosing an optimal number of CHs, decreasing

latency as much as possible and decreasing the

number of re-affiliations. Since there exists many

similarities between MANET and WSN, the

application of WCA is conjectured to be helpful and

beneficial for WSN also, however it surely needs

modifications in order to adapt it to wireless sensor

network environments.

2.1 Weighted Clustering Algorithms

for MANET

There is a vast amount research work carried out on

the weighted clustering algorithms. Each of these

studies has its own specific objective employing

various parameters. This section reviews the existing

weighted clustering approaches very briefly.

2.1.1 On-demand Weighted Clustering

Algorithm for Ad Hoc Networks

(WCA)

On-demand weighted Clustering algorithm (WCA)

is the original weighted clustering algorithm cited by

many other studies in the field (Chatterjee, et.al.,

2000). WCA is an on-demand algorithm, which aims

at optimizing the operation of the medium access

control protocol and decreasing the cost of both

communications and computations. In this

algorithm, cluster heads use ‘dual power’ mode in

order to transfer a message among clusters in a

higher transmission range. WCA procedure is as

follows:

1- Each node finds its neighbors and the node

degree

= |N[v]|=

∑

dist



v, v





T









∈,

where N[v] denotes the set of neighbors of node v,

dist(u,v) denotes the distance between nodes u and

v, and T

denotes the transmission range of a node.

2- Each node calculates its degree difference

∆

=|d

-δ|

where d

defines the number of node degree and δ

is a predefined ideal number of nodes placed

within a cluster.

3- Each node calculates the sum of the distances to

all its neighbors

∑

dist



v, v









∈







SENSORNETS2014-InternationalConferenceonSensorNetworks

4- Each node defines the running average of its

speed until current time T







∑



x



x













y











where x and y denote the rectangular coordinates

of the node in time.

5- Each node computes its cumulative time, P

which is the time a node can act as a cluster-

head.

6- Each node then calculates its total weight as

follows:

= w

;

where w

7- Considering global minima, the node with the

smallest weight value is selected as a cluster-

head.

The remaining nodes repeat the above steps until

the moment when each node starts acting as a cluster

member or a cluster-head. Nodes that belong to the

chosen clusters are not allowed to participate in the

clustering election again and steps 2 to 7 repeats for

the rest of the nodes that are not signed as a cluster

head or cluster member.

2.1.2 Weight based Adaptive Clustering in

Wireless Ad Hoc Networks (WBACA)

Weight based adaptive clustering in wireless ad hoc

networks (WBACA) (Dhurandher and Singh, 2005)

uses the local minima of weight instead of global

minima in order to decrease the number of re-

affiliations and the time delay within the network; it

specifies several parameters such as transmission

power, transmission rate, mobility, battery power

and the degree of a node to make clusters within a

mobile ad hoc network domain (Dhurandher and

Singh, 2005). An initial phase finds neighbourhoods.

Each node periodically broadcasts ‘Hello packet’

messages including its identification number. Nodes

lying within the same transmission range receive the

‘Hello packet’ messages and broadcast it to their

neighbours in response. The second phase includes

calculating weight values. Each node calculates its

weight and sends it to all its neighbours. The

clustering calculation is as follows:

*M+w

*B+w

*D+w

;

+ w

where M is node mobility, B is battery power, T

transmission range, D is degree difference, and T

transmission rate.

While running WBACA, in a case when there is

no node with the smallest weight, the node itself

becomes a cluster-head. Otherwise, the node sends a

‘Join-Req’ message to the neighbouring cluster-head

with the smallest weight. The cluster-head sends a

‘Join-Ack’ message to reply ‘Join-Req’ messages.

The cluster-head accepts nodes as its cluster

members until its degree becomes equal to the

defined threshold value. In a case when a node

cannot belong to any cluster, it identifies itself as a

cluster-head. Restarting the algorithm takes place at

the moment when a link between a node and its

cluster-head gets broken.

2.1.3 Weighted Clustering Algorithm using

Local Cluster-Heads Election for QoS

in MANETs

Weighted clustering algorithm using local cluster-

heads election (WCA-L) aims at turning isolated

nodes into cluster-heads and forms their clusters by

invoking an election immediately at the moment

when two cluster-heads are one-hop neighbors

(Bricard-Vieu and Nasser, 2006). The ordinary

nodes attempt to affiliate to another cluster and only

the gateway nodes that lie within the transmission

ranges of two different cluster-heads are successful.

The remaining nodes and the cluster-heads keep

electing clustering process, which is the same as the

one defined in WCA.

2.1.4 Entropy-based Weighted Clustering

Algorithm for Ad Hoc Networks

Entropy-based weighted clustering algorithm

(EBWCA) aims at demonstrating the uncertainty

concerning the amount of disorder within a network

(Wang and Bao, 2007). One of the parameters taken

into account in EBWCA is the relative position

between two nodes, which is set as below:

m,n

∑

|→,,



|





Where m and n are node IDs and t

refers to the time

instant of the i-th calculation and N is the number of

separate times, t

. And the entropy of the node m is

(t, Δt) that is defined as follows:

(t,Δ





∑







,



 





,



∈



 





where

(t, Δ





,

∑



,∈



defines the set of the node m’s neighbors and

C(F

) is the cardinality of set F

. The proposed

LifeTimeSensitiveWeightedClusteringonWirelessSensorNetworks

algorithm EBWCA then calculates overall weight

for node v as follows:

= c

+ c

(−H

) + c

where c

, c

are the corresponding weighing

factors.

2.1.5 Advanced Efficiency and Stability

Combined Weight based Distributed

Clustering Algorithm in MANET

This algorithm has a hierarchical structure, which

aims to optimize network performance by

minimizing energy consumption and improving

probable problems of efficiency and stability that a

network may face (Hwang, et.al., 2007). The initial

phase of this algorithm is the recognition of a

neighbour. Each node calculates its total weight as

follows:

Ev+w

∆

; w

where D

is the sum of distances of node v with all

its neighbours, M

is the average running speed of

node v, E

is the remaining amount of node v’s

battery and ∆

is the degree difference of node v.

Finally the node with smallest amount of W acts

as a cluster-head. This algorithm uses local minima

instead of global minima and moreover there is a

maintenance stage, which includes cluster

maintenance when cluster-head role is resigned and

when cluster member nodes move out.

2.1.6 Weight based Adaptive Clustering for

Large Scale Heterogeneous MANET

Weight based adaptive clustering algorithm

(WACHM) attempts to make a large scale

hierarchical MANET by utilizing heterogeneous

nodes to build various layers (Hwang, et.al., 2007).

The objectives of this algorithm are considered to be

choosing the optimal number of cluster-heads, using

optimal hop counts and defined dependency

probability and link stability within the network

domain.

The first step of the algorithm is to find

neighbours, which are categorized as two different

types: type-1 (cluster-heads) and type-0 (cluster

members). After that each node calculates the

following parameters:

-w

; w

Where AP

is the average of link stability Ps over all

neighbors:







∑





, 







; (j∈N (i))

is the average dependency probability P

over

all neighbors:

Aps=







∑











Finally the node with the highest W

is chosen as a

cluster-head this time and all the neighbors of the

selected cluster-head are not permitted to participate

in the election process.

2.1.7 Dynamic Energy Efficient Clustering

Algorithm for MANETs

Dynamic energy efficient clustering algorithm

(DEECA) contains two important stages: cluster

formation and network maintenance (Safa, et.al.,

2008). Two defined energy thresholds are taken into

account in order to equilibrate the amount of load

among cluster-heads within the network. At the

beginning all nodes have an undecided status which

means they do not belong to any cluster. After that

each node broadcasts ‘HELLO’ messages during

‘BROADCAST-PERIOD’ interval. Then each node

calculates its own weight as follows:

= w

v+w

; w

After the weight calculation process each node sends

‘HELLO’ messages including the amount of its

weight. Therefore, each node is aware of its

immediate neighbour’s weight. Lastly the node with

the minimum weight acts as a cluster-head and the

nodes in its immediate neighbourhood are its cluster-

members.

2.1.8 Improved Weight-based Clustering

Algorithm in MANETs

Improved weight-based clustering algorithm

(IWCA) has been proposed to overcome the problem

of high rate of re-affiliations that leads to an increase

in the network overhead (Zou, et.al., 2008). The

algorithm starts finding the neighbours of each node

and at the end calculates weight as follows:

w=w

∆

; w

where D

is the distance of a node with its

neighbours, M

is the average speed of node v, ∆

the degree difference of node v and P

is the

cumulative time P which shows how long a node

acts as a cluster-head in a network. Finally each

node chooses the node with minimum weight as a

cluster-head and moreover the isolated nodes also

act as cluster-heads.

SENSORNETS2014-InternationalConferenceonSensorNetworks

2.1.9 Energy Efficient and Stable Weight

based Clustering for MANETs

Energy efficient and stable weight based clustering

algorithm (EE-SWBC) tries not to send any

additional weight messages and select the most

promising node as a cluster-head and decrease the

amount of general overhead within the network

(Bouk and Sasase, 2008). It uses Grey Decision

Method (GDM) in order to calculate the weights of

nodes. Firstly, each node sends a ‘Hello message’

which includes ID, status, σ1(u), Mt(u), Pt(u), D(u)

and coordinates. Each node calculates the following

parameters:

• Node Degree of node u [σ1(u)]

• Average Speed of node u [Mt(u)]

• Residual Battery Power of node u[Pt(u)]

• Average Distance of node u [D(u)]

EE-SWBC assumes the node degree and the

residual battery power parameters to be the positive

criteria and the average speed and distance

parameters to be the negative criteria. Finally, the

maximum combined weight of neighbour nodes is

calculated by multiplying the weight factors w

the relations coefficient matrix utilized in GDM.

2.1.10 Flexible Weighted Clustering

Algorithm based on Battery Power

for MANETs

Flexible weighted clustering algorithm (FWCA)

aims to make a network stable by decreasing the

number of clusters and an amount of overhead due

to forming clusters (Hussein, et.al., 2008). Moreover

it tries to prevent nodes with less battery power act

as cluster-heads. FWCA includes two stages:

clustering algorithm and clustering maintenance.

The moment clustering algorithm starts, each node

broadcasts a ‘beacon’ message to recognize its

neighbors. All the sensor nodes create a neighbor list

considering the received beacons. Then each node

calculates its weight amount as below:

= w

SP+w

LCC+w

+ w

;

where SP is the spreading degree (meaning the

difference between cluster’s size (the threshold for

the cluster members) and the real number of

neighbours R(N)), LCC is the local clustering

coefficient (connectivity), BP is the remaining

battery power of the node and S

is the average speed

of the node i.

Finally a node with a minimum amount of

weight is selected as a cluster head. Clustering

maintenance is applied on the network in case of less

amount of battery power threshold and a node

separation from its cluster.

2.1.11 Enhanced Weighted Clustering

Algorithm for Mobile Networks

The objectives in enhanced weighted clustering

algorithm (EWCA) are achieving the minimum

number of affiliations and the general amount of

overhead during the formation process of clusters

and increasing the stability of clusters, system

performance and nodes’ life time through the ad hoc

network domain (Li, et.al., 2009). The moment the

clustering algorithm starts, each node calculates its

weight amount as following:

; w

where ∆

is the degree difference, D

is the sum of

the distances to all its neighbours, M

is mobility of

node i and E

is the consumed energy of a node.

Finally nodes with smaller weight are elected as

cluster-heads and the defined cluster-heads and

members are not allowed to participate in the

clustering elections. Moreover at the network

maintenance stage there is a feature of controlling

the battery power consumption of mobile sensor

nodes.

2.1.12 Maximal Weight Topology Discovery

in Ad Hoc Wireless Sensor Networks

This algorithm specifies two phases. The first one is

the ‘information exchange’ and the second one is the

‘cluster discovery’ (Fayyaz, et.al., 2010). The main

purpose of the algorithm is to minimize the number

of reconfigurations and the number of cluster-heads

within the network domain in order to achieve the

optimal topology for the network. After the neighbor

recognition step, each node calculates the following

parameters:

Ω

= ω

Ε+ω

Μ +ω

Δ+ω

Πϖ+ω

Δρ+ω

Τ;

+ω

where E is the node energy, M is the node mobility,

Δ is the node degree, Π

is the neighbouring node

positions, Δ

is the data rate and T is the target

revisit rate.

The node with the maximum amount of Ω is

selected as a cluster-head and following the second

phase (clustering discovery), it creates its own

cluster based on ‘color’ algorithm (Fayyaz, et.al.,

2010).

LifeTimeSensitiveWeightedClusteringonWirelessSensorNetworks

2.1.13 Efficient Cluster-head Election

Algorithm based on Maximum

Weight for MANET

Efficient cluster-head election algorithm (ECAM)

includes two stages of clustering and maintenance.

There are two parameters that are checked during

maintenance stage (Sivaprakasam and Gunavathi,

2011). The first one is the ‘mobility of a cluster’ and

the second one is the ‘cluster maintenance’. The

moment ECAM starts running, each node sends its

identification number to its neighbors in order to

build a neighbor's table. After that each node

calculates its weight as shown below:

n+ w

T(n)+w

;

where n is the set of node’s neighbours, S is the sum

of the distances between a node and all its

neighbours, T(n) is the speed of a node and T

is the

cumulative time that a node acts as a cluster-head.

Finally the node with the maximum weight acts

as a cluster-head and sends a ‘CH-MSG’ to its

neighbours in order to build its cluster.

2.2 Weighted Clustering Algorithms

for WSNs

It is necessary to mention that since MANET and

WSN are relatively similar networks, some of the

above weighted clustering algorithms for MANET

are applicable to WSN as well.

2.2.1 Clustering Algorithm for Localization

in WSNs

Clustering algorithm for localization in wireless

sensor networks (CFL) aims at achieving the

minimum number of clusters with maximum number

of nodes inside in order to improve the general

performance of weighted clustering algorithm

(Zainalie and Yaghmaee, 2008). At the moment the

CFL algorithm starts by all nodes broadcasting the

‘Hello’ message through the network and building

their ‘neighbour table’ based on received messages,

which includes estimation of distances also. Then

each node calculates its weight as follows:

=aN

+bE

; (a+b+c≤1)

where E

is the remaining energy, N

is the number

of node’s neighbours, P

is the transmission power

and W

is the combined weight.

Lastly, the node with the maximum weight value

acts as a cluster-head and sends a ‘CH-msg’ to its

neighbours and the nodes that receive this message

change their states to cluster members. The

remaining nodes, which do not belong to any

clusters, change to cluster-heads.

2.2.2 Improved Weighted Clustering

Algorithm for Heterogeneous WSNs

Improved weighted clustering algorithm (IWCA)

attempts to increase the network life time and in

addition to forming clusters it includes network

maintenance. Network maintenance checks two

thresholds for energy amount of nodes, which

triggers the recalculation of the clustering algorithm

(Hong, 2011). Each node calculates w

as follows:



+w5C

;

w1+w

where C

is the characteristic C of each node (C

=(C

* r

)/E

), C is a constant for amplification, r

is the

transmission rate, E

is the initial energy of a node,

is the distance of a node with its neighbours, ∆

the degree-difference, M

is the speed of a node and

is the cumulative time which shows how long a

node acts as a cluster-head in a network.

The node with minimum weight acts as a cluster-

head and makes its cluster.

2.2.3 Distributed Energy-Efficient

Hierarchical Clustering for WSNs

This algorithm utilizes two parameters – residual

energy and distance with neighbours – in order to

calculate the combined weight of each node

(Ding, et.al., 2005).

weight

(s) = (

∑





∈

,



) 













where R defines the cluster range, d specifies the

distance from node s to the neighbouring node u,

residual

is the residual energy in node S, E

initial

is the

initial energy in node S which is the same for all the

nodes and N

α,c

is the set of the neighbors of the node

S. It is assumed that the number of neighboUring

nodes of a cluster is at most 6.

3 LIFE TIME SENSITIVE

WEIGHTED CLUSTERING

ON WSN (LTS-WCA)

Various characteristics of WSNs, such as mobility

heterogeneity, large scalability requirement and

power restrictions, are all considered in the proposed

SENSORNETS2014-InternationalConferenceonSensorNetworks

model. It is expected that during the lifetime of a

sensor network, the network may face several

problems, such as: (1) lack of energy in sensor nodes

that fail in their attempt to cover the environment

properly; (2) overloaded cluster-heads; (3) existence

of some isolated sensor nodes in the network; (4)

fast energy depletion rate used for both transmission

and processing purposes. Life-time sensitive

weighted clustering algorithm (LTS-WCA) is a fully

distributed algorithm, which is applicable for

heterogonous mobile wireless sensor networks. It

aims to solve the predefined problems included in

the reviewed weighted clustering techniques and

modifies these previous works efficiently in order to

apply them on then WSN domain. Although LTS-

WCA is designed for heterogonous WSNs, it can be

used on homogeneous WSNs, too. There are several

significant modifications on the original version,

which can be listed as follows:

• LTS-WCA uses local minima instead of global

minimum, which means each decision can be made

by a group of nodes in a local manner and there is

no need for a node to get aware of the other nodes’

decisions and specifications.

• There is a specific life time assigned to each

protocol packet of a node in terms of hop counts in

order to limit packet retransmissions.

• Sensor nodes communicate in a multi-hop fashion

both for inter- and intra-communications.

• Several additional parameters are included in the

clustering algorithm to be used to calculate node

weights and to find efficient cluster heads. The

additional parameters used are:

• Er: remaining energy of a node

• Tr: transmission range of a node

• S: size of a cluster which a node as a cluster head

can support

• dv: number of 1-hop neighbours of a node

At the exact moment when clustering timer is

triggered through the network, each mobile wireless

sensor node gets prepared to follow the steps below:

Step 1: each node recognizes the nodes in its

neighborhood.

Step 2: each node calculates its parameters as

follows:

S = (NK

π)/A

Where S is the ideal number of cluster members

in a cluster,

K is the number of hops that a node can support

inside of its cluster in a case it becomes a cluster

head,

N is the number of nodes that can receive

transmitted packets from a source node,

A is the area of the network,

is the transmission range of a node,

is the speed of a node,

Er is the amount of residual energy of a node,

is the number of 1-hop neighbors of a node

Weight of a node:

w=(w

)/(w

S);

=1, w

=1.

Step 3: Each node prepares its data structures

considering the above calculations and broadcasts it.

Step 4: Each node compares its weight using other

neighbors’ weights.

Step 5: Each node checks whether it has the smallest

weight.

• If a node has the least weight, it sends a ‘ch-msg’

including its ID and weight to all its neighbours

and changes its state as a cluster head. Moreover

after receiving each ‘join-req’ it starts to accept

nodes until the number of nodes within its cluster

doesn’t exceed the defined threshold.

• If a node does not have the least weight amount, it

checks whether it receives any ‘ch-msg’. If so it

sends a ‘join-req’ to selected cluster head and after

receiving acceptance from the cluster head it

changes its state as cluster member.

• Isolated nodes, which cannot join to any cluster,

change their state as cluster heads.

• At the end of the clustering algorithm each node

has a cluster head or cluster member state within

the defined clusters. It is worth noting that during

the exchange of information among sensor nodes,

each node checks whether the received data is new

or not. If it is new, it propagates it to its 1-hop

neighbors considering the packet’s life time field,

if it is not, it simply drops it. Moreover, each node

updates the packet life time field once in every run

of the clustering algorithm considering its

remaining energy.

• During the clustering process, in case a node has a

possibility to join different clusters, it checks the

number of hops it is away from the available

cluster heads and selects the least distance. In case

of equality, it checks the residual energy amount of

the cluster heads and chooses the highest one and

joins it.

4 IMPLEMENTATION,

EVALUATION OF LTS-WCA

In our tests, we assumed that there are mobile

wireless nodes in a 1000*1000 square. They are

LifeTimeSensitiveWeightedClusteringonWirelessSensorNetworks

categorized into three types of nodes with speeds of

7, 5 and 3 m/s. Node transmission ranges are 200,

150 and 100 meters. Initial energy of nodes are 20,

15 and 10 Joules.

It is worth mentioning that although LTS-WCA

was designed especially for heterogeneous WSNs, it

can be used for homogenous WSNs and it can also

be applied on MANET, if the density of the mobile

nodes within the network is not large. This is

believed to be its biggest advantage.

Table 1: LTS_WCA parameters.

Parameter Value

Transmission ran

e 100, 150,200

Area L -1000

Traffic type CBR

Tx ener

0.036 Joules

Rx ener

0.024 Joules

Initial energ

20, 15, 10 Joules

umber of nodes 50, 100, 200

Max packet in if

200 packets

w1,w2,w3,w4,w5 0.5,0.5,0.4,0.4,0.2

In order to compare the result of LTS-WCA with

WCA and WBACA, we applied the same MANET

environment (1000*1000 square) with same values

of speed for nodes (10m/s). The following LTS-

WCA plots are obtained as averages of 50

consecutive runs of the simulation, each starting

with a new randomly assigned node distribution.

The simulation results of CFL, WCA and

WBACA are directly borrowed from the respective

publications (Dhurandher, and Singh, 2005),

(Zainalie and Yaghmaee, 2008). The comparison

results of LTS-WCA performance with the existing

weighted clustering algorithms on MANET are

shown below:

Figure 1: Comparing WCA, WBACA and LTS-WCA in

terms of number of cluster heads and number of nodes.

Figure 1 shows the comparison of LTS-WCA with

two different Weighted Clustering Algorithms

(WCA and WBACA) by considering two

parameters: number of cluster heads and number of

nodes. As seen in the figure, by increasing the

number of nodes the number of clusters increases

until the number of nodes reaches 30. After this

point in both WCA and LTS-WCA the number of

cluster heads decreases. The reason behind this is the

fact that when the node density is small, each node

takes a cluster head role in the environment.

However, by increasing the number of nodes further,

the possibility of nodes belonging to a cluster

increases and this decreases the number of cluster

heads, which in return decreases the energy

consumption to transmit data to sink. As figure 1

shows the performance of LTS-WCA is much better

than that of WCA (Chatterjee, et.al., 2000) and it is

also better than WBACA (Dhurandher and Singh,

2005) when the number of nodes gets larger.

Figure 2: Comparing WCA, WBACA and LTS-WCA in

terms of number of cluster heads and transmission range.

Figure 2 presents results considering two

parameters, namely the number of cluster heads and

transmission range. By increasing the node

transmission range within the network, the number

of cluster heads decreases. As can be seen in the

figure the performance of LTS-WCA in decreasing

the number of clusters and therefore transmission

energy consumption is much better than that of the

other two algorithms.

Figure 3: Comparing CFL and LTS-WCA in terms of

number of clusters and transmission range.

SENSORNETS2014-InternationalConferenceonSensorNetworks

Figure 3 shows the comparison between LTS-WCA

and CFL (Zainalie and Yaghmaee, 2008) algorithm

on WSN. By increasing the transmission range, the

number of clusters within the network decreases and

this leads to the decrease of the amount of energy

needed to transmit data from the source to a sink. As

the plot represents LTS-WCA has a considerably

better performance in comparison with CFL

(Zainalie and Yaghmaee, 2008) algorithm.

Figure 4: Comparing CFL and LTS-WCA in terms of

number of nodes and time needed for clustering.

Figure 4 illustrates the change in the time needed for

clustering vs the number of nodes in WSN. As seen

in the figure, LTS-WCA is quite successful to

decrease the clustering time in comparison with CFL

(Zainalie and Yaghmaee, 2008).

Figure 5: LTS-WCA life time performance in function of

number of nodes (homogenous network).

Figures 5, 6 and 7 present the performance of LTS-

WCA in a homogenous WSN to show how energy

efficient it is in terms of network life time. As was

mentioned earlier, the moment the first node dies is

considered as a network life time in LTS-WCA for

simplicity. In Figure 5 by increasing the number of

nodes, the network life time increases gradually.

Figure 6 shows the considerable increase the

network life time if initial energy of nodes within the

environment is increased. Figure 7 presents the

decrease of the network life time of WSN while

Figure 6: LTS-WCA life time performance in function of

energy of nodes (homogenous network).

Figure 7: LTS-WCA life time performance in function of

transmission range of nodes (homogenous network).

node transmission range increases. The reason

behind this is the fact that by increasing the

transmission range of nodes, the size of clusters

increases, too. Finally cluster heads become

overloaded and they start to lose their energy much

faster. As a result, the network life time also

decreases.

Figure 8 represents the performance of LTS-

WCA on a heterogeneous WSN. By increasing the

number of nodes, the network life time also

increases.

Figure 8: LTS-WCA life time performance in function of

transmission range of nodes (heterogeneous network).

LifeTimeSensitiveWeightedClusteringonWirelessSensorNetworks

5 CONCLUSIONS

In the present work, we studied the vast amount of

research done in the field of weighted clustering

algorithm for two different network types, namely

mobile ad hoc networks and wireless sensor

networks. We examined their main motivations

concentrating mostly on the energy efficiency and

network overhead. Since in WSN life time is

considered to be a vital issue, researchers mostly

take it as a significant parameter to be improved

within their proposed clustering algorithms (Hong,

2011), (Ding, et.al., 2005). However, along with life

time, the issue of energy efficiency plays an equally

important role. Therefore, it became the second

emphasized area of the present study.

LTS-WCA is a weighted clustering algorithm

which is designed in this work specifically for

distributed heterogeneous wireless sensor networks.

The algorithm includes two phases: clustering and

network maintenance. It employs five key

parameters in order to choose the best cluster head

through the network environment. These parameters

are transmission range of a node (Tr), minimum

distance to a neighbour cluster’s cluster head

(Dmin), speed of a node (Mv), degree of a node

(dv), remaining energy of a node (Er) and number of

nodes that a node can handle inside of its cluster in

case it becomes a cluster head (S). After choosing

cluster heads and grouping the network nodes in

clusters, the maintenance phase starts. In the

maintenance phase, three parameters are checked

periodically within the network environment: the

residual energy of mobile wireless sensor nodes, the

mobility of sensor nodes and the amount of load put

on a cluster head. In the present paper, maintenance

part is not implemented since it is proposed as an

enhancement.

The main purpose of LTS-WCA is to overcome

the problems which a wireless sensor network faces.

LTS-WCA increases network life time by

decreasing the number of clusters within the network

environment. Decreasing the number of clusters

leads to less usage of transmission power and finally

keeping the nodes alive for much longer within the

network environment. Moreover decreasing the time

needed to group the network into clusters also in

increasing the network life time and LTS-WCA acts

successfully to increase the overall network life time

on a Wireless Sensor Network.

One of the advantages of LTS-WCA is that it is

applicable to MANET and homogenous networks

also. As a result, as shown in our simulation study, it

has a much better performance in terms of energy

efficiency in comparison with existing weighted

clustering algorithms on both MANET and WSN

such as WCA (Chatterjee et.al., 2000), WBACA

(Dhurandher and Singh, 2005) and CFL (Zainalie

and Yaghmaee, 2008).

In terms of increasing energy efficiency and

network life time, there is still a lot of work to be

done. There are several parameters such as

‘transmission range’, ‘number of neighbours’,

‘degree differences’, and ‘remaining battery power’

and ‘distances with neighbours’, which play

significant roles in the process of selecting cluster-

heads and clustering formations, and these

parameters should be thoroughly worked out and

developed further. There is still lack of research

done in this area and scant written materials

covering the aforementioned issues.

Further improvements on weighted clustering

algorithms should concentrate on clustering

formation and cluster-heads election for creating a

more stable network structure with less energy cost.

In order to maintain the network, efficient thresholds

should be used in terms of energy amount of nodes,

mobility of nodes and cluster size; this should be

done in order to decrease the number of re-

affiliations as well as the number of re-clustering the

network domain. Replacing some parameters for

calculating the combined weight with some other

parameters may help to keep the amount of load on

the cluster-head balance and decrease the general

overhead within the network.

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