Energy-Efficient Fuzzy-Logic-Based Clustering Technique for Hierarchical Routing Protocols in Wireless Sensor Networks
<p>Fuzzy system control model.</p> "> Figure 2
<p>Simple WSN scenario for location suitability computation.</p> "> Figure 3
<p>First and second vicinities of nodes A and B.</p> "> Figure 4
<p>Membership Functions of the fuzzy sets.</p> "> Figure 5
<p>WSN area divided into virtual identical rectangles.</p> "> Figure 6
<p>A snapshot of clustering output in <span class="html-italic">FL-EEC/D</span>.</p> "> Figure 7
<p>Lorenz curve and the line of equality for the distribution of wealth.</p> "> Figure 8
<p>FND of FL-EEC/D against LEACH, <span class="html-italic">K</span>-means-LEACH, and FL[1]/D (BS at the center of WSN).</p> "> Figure 9
<p>10PND of FL-EEC/D against LEACH, <span class="html-italic">K</span>-means-LEACH, and FL[1]/D (BS at the center of WSN).</p> "> Figure 10
<p>QND of FL-EEC/D against LEACH, <span class="html-italic">K</span>-means-LEACH, and FL[1]/D (BS at the center of WSN).</p> "> Figure 11
<p>HND of FL-EEC/D against LEACH, <span class="html-italic">K</span>-means-LEACH, and FL[1]/D (BS at the center of WSN).</p> "> Figure 12
<p>Average improvement percentage of FL-EEC/D over LEACH, <span class="html-italic">K</span>-means-LEACH, and FL[1]/D for network lifetime (BS at the center of WSN).</p> "> Figure 13
<p>FND of FL-EEC/D against LEACH, <span class="html-italic">K</span>-means-LEACH, and FL[1]/D (BS at the corner of WSN).</p> "> Figure 14
<p>10PND of FL-EEC/D against LEACH, <span class="html-italic">K</span>-means-LEACH, and FL[1]/D (BS at corner of WSN).</p> "> Figure 15
<p>QND of FL-EEC/D against LEACH, <span class="html-italic">K</span>-means-LEACH, and FL[1]/D (BS at the corner of WSN).</p> "> Figure 16
<p>HND of FL-EEC/D against LEACH, <span class="html-italic">K</span>-means-LEACH, and FL[1]/D (BS at the corner of WSN).</p> "> Figure 17
<p>Average improvement percentage of FL-EEC/D over LEACH, <span class="html-italic">K</span>-means-LEACH, and FL[1]/D for network lifetime (BS at the corner of WSN).</p> "> Figure 18
<p>Live nodes vs. rounds for FL-EEC/D and LEACH.</p> "> Figure 19
<p>Percentage of total remaining energy per round for FL-EEC/D, LEACH, <span class="html-italic">K</span>-means-LEACH, and FL[1]/D.</p> "> Figure 20
<p>The Gini Index of the remaining energy per round for FL-EEC/D, LEACH, <span class="html-italic">K</span>-means-LEACH, and FL[1]/D.</p> ">
Abstract
:1. Introduction
2. Literature Review
3. The Proposed Fuzzy Model and WSN Clustering Technique
3.1. Linguistic Variables’ Measurement and Normalization
- Remaining Energy: Selecting sensor nodes with higher energy as CHs improves network lifetime by balancing energy consumption through the WSN’s nodes.is normalized by Equation (1), where is of the current node and and are the maximum and minimum values among all candidate nodes, respectively. Hence, the normalized will be zero for the node with the lowest remaining energy and 100 for the node with the highest remaining energy. The normalized values for the rest of nodes are between zero and 100 according to their relative position between the highest and the lowest values.
- Distance from the BS: The lower the distance between CHs and the BS, the lower the consumed energy. Sensor nodes closer to the BS have to be given higher opportunities to be CHs over farther ones.BS_Distance is normalized as a percentage value to the distance between the furthest candidate node and the BS using Equation (1), where Max is the distance from the BS to furthest candidate node, Min is the distance of the nearest node to the BS, and Valueis the distance of current node from the BS.For example, if the of the farthest node from the BS is 80 m, the of the closest node to the BS is 30 m, and the of current node is 50 m, then the normalized of the current node is:
- Location suitability: This criterion measures how suitable a node location is as a CH with respect to surrounding nodes within a predefined range. A more suitable location for a CH node is a location with lower total communication energy.Location suitability for any node is measured by averaging the energy consumed locally by the sensor nodes located around the current node within a pre-defined range. We are interested in the nodes located within a predefined range as long as they are not closer in distance to any other pre-selected CH because they will be probably members of the current node if this current node wins CH election.Since we use the average of the consumed energies for the current node, we use the term average of local consumed energy and shorten it as to point out the location suitability. Note that we measure the average of the consumed energy rather than the total consumed energy to guarantee that the size of the group does not have an effect on the normalized value.Some consider, mistakenly, that if a node has a lower sum of distances to its future probable members, then is situated at a more suitable location to become CH. This stems from the assumption that the nodes closer to the centroid of the group will consume less total energy. However, since the energy is exponentially proportional to the distance, it becomes necessary to consider members with extreme distances. This means that the location with the minimum average distances to other surrounding nodes in a predefined range is not always the most suitable location for a node to become a CH since it may not always result in minimum total consumed energy for its surrounding group of nodes.To illustrate this idea, consider the scenario depicted in Figure 2. Here, node G has the minimum average distance of m from its surrounding nodes, and is the closest to the centroid. If selected as a CH, it will result in an average consumed energy of J, for one byte of data from each neighboring node. On the other hand, node F has an average distance of m, but results in an average consumed energy of J. For that reason, we base the computation of location suitability for a node to become a CH on the consumed energy rather than the total distances.
- Density of surrounding nodes: Selecting CHs surrounded by dense nodes over CHs surrounded by sparse nodes improves the energy consumption by increasing the opportunity for nodes with more neighbors in their vicinity to become CHs. Thereby, the local consumed energy for the group members is decreased.Density is calculated by the number of surrounding nodes within a predefined range normalized using Equation (1), where is the density of the current node, is the maximum density value through all candidate nodes, and is the minimum density value through all candidate nodes.
- Compaction of surrounding nodes: Group compaction is a measure of how the surrounding nodes are distributed around the current node. A node surrounded by more neighbors in a closer vicinity is considered of higher compactiondegree. Selecting a node with a higher compactiondegree minimizes the total energy consumption. This criterion is important to assign different priorities for CH candidates with the same number of surrounding nodes within a predefined range. In other words, it is beneficial for distinguishing candidates surrounded by the same density of sensor nodes.Compaction is calculated as the ratio of the number of nodes located within the first vicinity region to those located within the second vicinity region. The first vicinity region is that region that is within half of a predefined radius distance, whereas the second vicinity region is the one that is within the nodes’ radius.As shown in Figure 3, the small circles surrounding A and B are considered as the first vicinities, and the larger ones are considered as the second vicinities for nodes A and B. The distance to which to extend the first vicinity is a design parameter and may be any fraction of the radius.To normalize the Compaction, we use Equation (1), where is the Compaction value of current node, is the maximum Compaction value through all candidate nodes, and is the minimum compaction value through all candidate nodes.
3.2. Fuzzy Sets
3.3. The Proposed Clustering Technique FL-EEC/D
Algorithm 1 Calculation of the minimum forced distance between CHs. | |
functionCalc_Min_Dist() | N: List of live nodes |
p: percentage of CHs in WSN | |
: length of X-dimension, : Length of Y-dimension | |
← | : desired # of clusters |
c ← 1 | c: # of of regional columns, initially set to 1 |
r ← 1 | r: # of regional rows, initially set to 1 |
← | : difference between # of created rectangles and the desired # of clusters, initially set to |
I ← 1 | |
while do | |
J ← I | |
while do | |
if then | |
← | |
c ← I | |
r ← J | |
end if | |
J ← | |
end while | |
I ← | |
end while | |
← | |
← | |
d ← | |
return d | d: minimum distance between CHs |
end function |
Algorithm 2 Clustering based on minimum separation distance enforcement between CHs. | |
procedureWSN clustering | |
inputs: | |
% N: set of live nodes % | |
← d | % d: minimum forced distance % |
p | % p: Percentage of live nodes to become CHs % |
← | % : number of the desired CHs % |
outputs: | |
% set of CHs % | |
% set of clusters % | |
steps: | |
1) For each node , if the distance from to the closest already selected is less than d, then calculate each of the fuzzy input variables: Energy, BS_Distance, Density, Compaction AVG_Energy. | |
2) Calculate the fuzzy output variable chance for each based on the linguistic variables using the proposed fuzzy inference system | |
3) Select with the highest chance value among the nodes located away from any pre-selected by the distance d | |
4) Repeat Steps 1–4 until reaching | |
5) Form clusters, , by joining each to the closest | |
end procedure |
4. Performance Evaluation
4.1. Simulation Parameters
4.2. Network Model
- All sensor nodes are randomly distributed over a two-dimensional area.
- All sensor nodes are homogeneous in terms of processing and communication capabilities. Furthermore, they have the same battery, radio, sensing, and storage capabilities.
- There are no recharging capabilities.
- The BS is able to estimate the locations of the sensor nodes by using any localization technique. This may be based on utilizing GPS [57,58] or by adopting GPS-free localization such as weighted centroid localization [59,60,61], which is based on the received signal strength. Generally, a small error in localization will not be significant for the overall clustering result since the values are calculated as relative variances between the lowest and highest values. These relative variances are later fuzzified (expressed as linguistic variables). The percentage of cluster heads is supposed to be 5% of the total number of sensor nodes in the WSN.
- Cluster heads are re-selected periodically.
4.3. Performance Metrics
4.4. Evaluation of FL-ECC/D
5. Conclusions and Future Work
Author Contributions
Funding
Conflicts of Interest
Abbreviations
WSN | Wireless Sensor Network |
CH | Cluster Head |
BS | Base Station |
FL-EEC/D | Fuzzy Logic-based Energy-Efficient Clustering based on minimum separation Distance enforcement between CHs |
LEACH | Low Energy Adaptive Clustering Hierarchy |
FIS | Fuzzy Inference System |
HRP | Hierarchical Routing Protocols |
PEGASIS | Power-Efficient Gathering in Sensor Information Systems |
DPSO | Discrete Particle Swarm Optimization |
FND | First Node Dead |
10PND | 10% of Nodes Dead |
QND | Quarter of Nodes Dead |
HND | Half of Nodes Dead |
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Class | Single Layer | Cross Layer | |
---|---|---|---|
Cluster Based | Centralized | Sensors are organized into clusters, and transmissions go through CHs. In this approach, node locations are estimated by the BS. This benefits from the global knowledge of the network and achieves a more efficient clustering compared to the distributed approach. Examples appear in [19,25,26,29], and [32]. | Information is collected and combined from different network layers to be utilized for CH election. The works in [49] and [51] follow this approach. |
Distributed | Sensors are organized into clusters in a distributed manner, and transmissions go through CHs. A drawback of this approach is that it is confined to local information, and this may lead to non-optimal WSN clustering [6,12,24,27,52]. | ||
Chain Based | Proactive | Sensors are periodically organized into chains through which the transmissions pass. An example of this approach is found in [7]. | |
Reactive | Sensors are organized as chains through which the transmissions pass. Routes change immediately in response to the changes of relevant parameters of interest [21]. |
SN. | Input Variables | Output Variable | ||||
---|---|---|---|---|---|---|
Energy | BS_Distance | AVG_Energy | Density | Compaction | Chance | |
1 | Low | Close | Low | Low | Low | LMid |
2 | Low | Close | Low | Low | High | HMid |
3 | Low | Close | Low | High | Low | HMid |
4 | Low | Close | Low | High | High | High |
5 | Low | Close | High | Low | Low | Low |
6 | Low | Close | High | Low | High | LMid |
7 | Low | Close | High | High | Low | LMid |
8 | Low | Close | High | High | High | HMid |
9 | Low | Medium | Low | Low | Low | VVLow |
10 | Low | Medium | Low | Low | High | VLow |
11 | Low | Medium | Low | High | Low | VLow |
12 | Low | Medium | Low | High | High | LLMid |
13 | Low | Medium | High | Low | Low | VVLow |
14 | Low | Medium | High | Low | High | VVLow |
15 | Low | Medium | High | High | Low | VVLow |
16 | Low | Medium | High | High | High | VLow |
17 | Low | Far | Low | Low | Low | VVLow |
18 | Low | Far | Low | Low | High | VVLow |
19 | Low | Far | Low | High | Low | VVLow |
20 | Low | Far | Low | High | High | VVLow |
21 | Low | Far | High | Low | Low | VVLow |
22 | Low | Far | High | Low | High | VVLow |
23 | Low | Far | High | High | Low | VVLow |
24 | Low | Far | High | High | High | VVLow |
25 | Medium | Close | Low | Low | Low | High |
26 | Medium | Close | Low | Low | High | VVHigh |
27 | Medium | Close | Low | High | Low | VVHigh |
28 | Medium | Close | Low | High | High | VVHigh |
29 | Medium | Close | High | Low | Low | HMid |
30 | Medium | Close | High | Low | High | High |
31 | Medium | Close | High | High | Low | High |
32 | Medium | Close | High | High | High | VVHigh |
33 | Medium | Medium | Low | Low | Low | LLMid |
34 | Medium | Medium | Low | Low | High | Mid |
35 | Medium | Medium | Low | High | Low | Mid |
36 | Medium | Medium | Low | High | High | HHMid |
37 | Medium | Medium | High | Low | Low | VLow |
38 | Medium | Medium | High | Low | High | LLMid |
39 | Medium | Medium | High | High | Low | LLMid |
40 | Medium | Medium | High | High | High | Mid |
41 | Medium | Far | Low | Low | Low | VVLow |
42 | Medium | Far | Low | Low | High | VVLow |
43 | Medium | Far | Low | High | Low | VVLow |
44 | Medium | Far | Low | High | High | Low |
45 | Medium | Far | High | Low | Low | VVLow |
46 | Medium | Far | High | Low | High | VVLow |
47 | Medium | Far | High | High | Low | VVLow |
48 | Medium | Far | High | High | High | VVLow |
49 | High | Close | Low | Low | Low | VVHigh |
50 | High | Close | Low | Low | High | VVHigh |
51 | High | Close | Low | High | Low | VVHigh |
52 | High | Close | Low | High | High | VVHigh |
53 | High | Close | High | Low | Low | VVHigh |
54 | High | Close | High | Low | High | VVHigh |
55 | High | Close | High | High | Low | VVHigh |
56 | High | Close | High | High | High | VVHigh |
57 | High | Medium | Low | Low | Low | HHMid |
58 | High | Medium | Low | Low | High | VHigh |
59 | High | Medium | Low | High | Low | VHigh |
60 | High | Medium | Low | High | High | VVHigh |
61 | High | Medium | High | Low | Low | Mid |
62 | High | Medium | High | Low | High | HHMid |
63 | High | Medium | High | High | Low | HHMid |
64 | High | Medium | High | High | High | VHigh |
65 | High | Far | Low | Low | Low | Low |
66 | High | Far | Low | Low | High | LMid |
67 | High | Far | Low | High | Low | LMid |
68 | High | Far | Low | High | High | HMid |
69 | High | Far | High | Low | Low | VVLow |
70 | High | Far | High | Low | High | Low |
71 | High | Far | High | High | Low | Low |
72 | High | Far | High | High | High | LMid |
Parameter | Value |
---|---|
Data Packet Size | 500 bytes |
Initial Energy | 2 J |
50 nJ/bit | |
10 nJ/bit/m bytes | |
5 nJ/bit/signal | |
0.0013 nJ/bit/m | |
Threshold Distance | 87 m |
Deployment Method | Random |
© 2019 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).
Share and Cite
Hamzah, A.; Shurman, M.; Al-Jarrah, O.; Taqieddin, E. Energy-Efficient Fuzzy-Logic-Based Clustering Technique for Hierarchical Routing Protocols in Wireless Sensor Networks. Sensors 2019, 19, 561. https://doi.org/10.3390/s19030561
Hamzah A, Shurman M, Al-Jarrah O, Taqieddin E. Energy-Efficient Fuzzy-Logic-Based Clustering Technique for Hierarchical Routing Protocols in Wireless Sensor Networks. Sensors. 2019; 19(3):561. https://doi.org/10.3390/s19030561
Chicago/Turabian StyleHamzah, Abdulmughni, Mohammad Shurman, Omar Al-Jarrah, and Eyad Taqieddin. 2019. "Energy-Efficient Fuzzy-Logic-Based Clustering Technique for Hierarchical Routing Protocols in Wireless Sensor Networks" Sensors 19, no. 3: 561. https://doi.org/10.3390/s19030561
APA StyleHamzah, A., Shurman, M., Al-Jarrah, O., & Taqieddin, E. (2019). Energy-Efficient Fuzzy-Logic-Based Clustering Technique for Hierarchical Routing Protocols in Wireless Sensor Networks. Sensors, 19(3), 561. https://doi.org/10.3390/s19030561