A Novel Energy Efficient Spherical Routing Model for Dynamic Route Discovery in Wireless Sensor Networks

DOI : 10.17577/IJERTCONV4IS29015

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A Novel Energy Efficient Spherical Routing Model for Dynamic Route Discovery in Wireless Sensor Networks

Jai Prakash Prasad

Research Scholar, VTU Research Resource Centre Visvesvaraya Technological University

Belgaum, Karnataka, India

Dr. Suresh Chandra Mohan

Professor, Dept. of ECE BIET, Davangere Karnataka, India

Abstract:- Deployment of Wireless Sensor Networks (WSN) has achieved tremendous growth in recent years causing it to become one of the top developing areas of the low data capacity communications system. The significant issue in WSN is the constraint on energy and processing resources ability in mote which reduces down potential functionality of sensor node. Also continuous use of a single shortest route between source and sink results in a shorter life span of a sensor node which in turn degrades the network performance. The important consideration for the wide scale WSN is the progress on power utilization efficiency. Therefore clustering is important energy efficient routing techniques for WSN. The proposed Spherical Routing protocol (SpRP) are designed and its performance metrics are evaluated as i.e. number of packet transmitted, number of packet received, percentage in packet delivery, throughput and average residual energy and compared with the performance metrics calculations of Modified LEACH (M- LEACH) clustering Protocol. The conclusion from the analysis of results is that SpRP protocol achieves better optimized performance contrast to popular M-LEACH protocol. The projected work outcomes from the performance metrics can adds extra life time in a WSN to provide superior Quality of Service (QoS).

Keywords Energy; Data Capacity; Spherical Routing; M- LEACH; Life span; Quality of Service.

  1. INTRODUCTION

    In Wireless Sensor Network (WSN) several wireless sensors nodes are deployed over the wide geographical area where each node function is to sense input attributes surrounding to its environment. For transmitting the useful message to the base station sensor nodes construct an optimized shortest path using intermediate sensor nodes. Each Sensor Nodes coordinated to its neighbor sensor nodes for successful routing of information. There are wide verities of existing routing scheme which optimizes best bath between source nodes to destination node. Most of the routing methods adopt the approach which uses best routing metrics for efficient energy and resource utilization of motes.

    Sensor nodes are limited in its power and computational power which limits the operation on resource constrained wireless sensor nodes.

    Fig.1. A general WSN Structure

    The blueprint of sensor node includes sensor, processor, memory and radio trans-receiver as its main components to execute a task along with neighboring nodes. The figure 2 shows the main component as block diagram of a WSNs node.

    The various subcomponents of sensor nodes are sensors, power supply, ROM & RAM, memory, microcontroller and trans-receiver. The sensor components are defined in table I.

    Fig. 2. WSN node functional block diagram

    Component

    Definition

    Microcontroller

    It fetches data from the storage element

    & performs the computational task.

    ROM & RAM

    It is used for storing information.

    Trans-receiver

    Transmission & Reception of

    information.

    Sensor(s)

    To sense input attributes.

    Battery

    WSN node components draw energy

    from it.

    Component

    Definition

    Microcontroller

    It fetches data from the storage element

    & performs the computational task.

    ROM & RAM

    It is used for storing information.

    Trans-receiver

    Transmission & Reception of

    information.

    Sensor(s)

    To sense input attributes.

    Battery

    WSN node components draw energy

    from it.

    Table I. Components of Sensor Node

    Sensor nodes are used in several applications with optimum uses of WSN node energy. The application of WSN are usually ideal in monitoring of environmental, distributed control system, radioactive sources detection, agricultural & farm, internet, defense and surveillance.

    WSN is capable of being used for large scale area tele-communication linkage across different geographical regions. The design and deployment of WSN across various separate parts of wide region and their interconnectivity can be done and extended for the covering the area of complete earth by formation of group of networks which is approximated into spherical form as shown in figure 3.

    Fig.3. Globe coverage structure using WSNs

  2. WSN ROUTING: A REVIEW

    The popular Grid based Routing Techniques are reviewed to understand the existing routing techniques in WSN and these surveys papers details have shown optimized results to improve the network lifetimes compare to other types WSN routing schemes.

    LEACH (Low Energy Adaptive Clustering Hierarchy) is the widely accepted hierarchical routing method for wireless sensor networks [1]. LEACH arbitrarily opts for sensor nodes

    as cluster heads, with the intention that the power dissipation during communication considering the base station is extend to all sensor nodes. LEACH uses one hop routing with each node able to pass on message directly to the cluster head and the base station. Therefore, this method is not suitable to networks in the application of large coverage area. In addition, the design of active clustering includes more overhead such as changes in head, advertisements etc., which might weaken the gain in power consumption.

    GBDD (Grid Based Data Dissemination) [6] grid cell area is formed by twin radio range of a mote. In GBDD grid building process starts depending on sink which was first involved in communication. Route metric are followed as when if valid grid is present, sink finds out nearest spot node. The benefit of this protocol is that it guarantees uninterrupted data release from source nodes to base station. But it consumes more power when the rate is very high.

    ARA (Adaptive Routing Algorithm) [8] the network existence is improved by considering the sensor node outstanding energy and it creates an adaptive route path which is based adaptive routing algorithm useful for grid structure of WSN. The simulation result indicates the square sensor network offers key benefits contrast to the hexagonal sensor network, even though it has more coverage surface. ARA scheme is also favorite for arbitrarily deployed sensor nodes. The nodes are formed in clusters and the clusters are arranged in grid topologies. This way the cluster-head can be considered as a node from the grid.

    GBDAS (Grid-Based Data Aggregation Scheme) [9] protocol partitioned the sensors ground into a grid of cells to optimize data transmission to the Base Station. In message collecting round, member nodes take turns to be cell head. Likewise, cell heads in the chain also take turns to be the chain leader. Therefore, the power consumption of sensor nodes is evenly distributed so as to exploit their lifetimes. As a result, the life span of the whole WSN extends.

    CBDAS (Cycle-Based Data Aggregation Scheme) [10] node find-out which cell it relate to by a simple arithmetic process. Grid-based WSN build the grid infrastructure by dividing the complete geographical section into a grid of cells. Better lifetime is achieved with this scheme of the sensor nodes to improve the lifespan of the complete sensor network. This method outperforms the other grid based approach in terms of optimizing power level, dimension of the network, and compactness of the node.

    TTDD (Two-Tier Data Dissemination) [11] provides various mobile base stations data delivery. Assuming that sensor nodes are motionless and position aware, each data source proactively constructs a grid topology for disseminating data to the mobile sinks. Also, sensor nodes are location aware and stationary, whereas base station may move their locations energetically depending on situation. The simulation result shows that TTDD perform release of data from many sources to many mobile sinks with optimized performance.

  3. METHODOLOGY

    The abstract representation of projected Wireless Sensor Network framework is represented by figure 4.

    Fig.4. Abstract Representation of Proposed WSN Model

  4. MODIFIED LEACH PROTOCOL

    LEACH (Low Energy Adaptive Clustering Hierarchy) protocol is an efficient energy resourceful clustering algorithm for wireless sensor network as shown in figure 5, in which entire network is separated into several numbers of clusters of networks. Each cluster nominates a node which acts as a cluster heads based on its threshold value, which establishes communication link with one or more different cluster heads for the routing of the data to the sink or base station. In LEACH method a cluster head is elected based on the threshold value from number of nodes n as Th (m) of the latest stage if the number is small contrast to the threshold as follows:

    Fig.5. Modified LEACH Protocol

    The LEACH protocol which is designed, modeled and implemented using Network Simulator-2.35 as shown in Fig

    6. The performance metric obtained and calculated from the simulator trace file is shown in result section.

    Fig..6. LEACH Simulation Model

    Th(m) = ,

    Th(m) = ,

    1 ( 1 )

    if m G

    Considered wireless sensor network model of 20 nodes. Assuming node 0 is base station. Remaining 19 nodes

    0, otherwise

    Where, P indicates the fraction of desired cluster heads, and

    r indicates the in progress round, and G represent the nodes set that is so far not chosen as CHs in the last 1/P rounds.

    are separated in to three different groups of clusters. In each cluster based on utmost energy value of node a cluster head is elected. The function of cluster head is to gather & aggregate data from node of local set member and forwarding of data towards base station or other cluster leader. Figure 6 represents three different clusters which are indicated by three different colors. Dynamically number of clusters construction takes place and cluster heads are selected in conditions of highest energy value of the sensor node.

  5. SPHERICAL ROUTING PROTOCOL (SPRP): A PROPOSED METHOD

    In this section a novel concept of Spherical Routing Protocol (SpRP) is proposed. The SpRP architecture is shown in Fig 7 to Fig 9. Here sensor nodes are randomly

    dispersed over a geographical region to monitor its

    environment. Sensor node coordinates each other to help in constructing a spherical routing link between source nodes to base station via intermediate nodes to transmit observed

    data. In SpRP, sensor nodes promote their request such as messages for advertisement with the path which is equivalent to a logarithmic spherical curve; where as a sink node transmits its query message with the path which is equivalent to a logarithmic spherical curve opposite way to the advertisement path.

    For the resource constrained wireless sensor nodes logarithmic spherical curve is chosen which is ideal for

    SpRP. It is assumed that in advance the spherical curve related required parameters are in prior installed to every sensor node. When sensor nodes observe some events and ready to get disseminated, it initiates the spherical dissemination. The picking of the next hop neighbor node depends on the use of Spherical Path Search Protocol (SPSP) which fits the planned best spherical path and then to the chosen sensor node it sends an advertisement which includes the position and ID of the preceding hop node, the spherical direction of the preceding hop node, and some more parameters like advertisement TTL (Time-To- Live), the utmost hop number of the distribution path, etc.

    After receiving an advertisement packet by a sensor node, it stores a local copy of the advertisement message, then make use of the same SPSP to decide a neighbor as the subsequent hop, and then transfer the advertisement message. By this approach, forwarding of the advertisement message takes place hop by hop in the sensor network which follows a spherical like track. When the spherical link reaches the edge, or the when limitation on hop is reached routing will stop when it meets some preset condition. In opposite direction query procedure is similar to the dissemination procedure. When a query is initiated by a sink node, the query follows the opposite way spherical path till it satisfy the spherical dissemination, or the end condition is fulfilled. The source node can once in a while bring up to date the information along the spherical path, or work in an unexpected form that starts the spherical distribution every time the concerned event is observed.

    At ith hop SPSP uses path search algorithm which is shown by the following equation:

    ( ) +

    ( ) +

    Max ——- (A)

    The spherical routing formation takes place in the sensor fields with predetermined angular position between two or more nodes. One or more layers of spherical routing paths may be formed depending on applications as shown in Fig 9.

    Fig.7. A Spherical Path Formation

    Fig.8. A Spherical Routing

    =1 ( )

    = 1

    = 1

    Subject to,

    =1

    Where, w denotes a node, kc denote the spherical angle weight and ke denote the distance weight. In the above equation, the sum of weight of the period spherical angle

    and the distance to the ideal spherical is represented as the

    cost function.

    Fig.9. SpRP Model using NS-2.35

  6. RESULTS & DISCUSSIONS

The analyzed and evaluation of proposed SpRP method are done using network simulator (NS-2.35). Table II shows the detail of the parameters used in the simulation. The M- LEACH is compared with the proposed research work and the results are shown in Table III. The NS-2.35 simulated

Result of SpRP outperforms existing M-LEACH protocol.

Table II: WSN Model Simulation parameters

Table III. The average throughput which is defined as average transform rate that is improved for SpRP over M- LEACH. Average Residual Energy metric is concerned with

the network lifetime and result shows the average dissipation

of energy per node over time in the network. As shown in fig.10 different performance metrics computed for analysis indicate that SpRP outperforms the M-LEACH protocol.

1400

1200

1000

800

600

400

NS-2 Parameters

Value

Types of Channel

Wireless Channel

Max Packet in IFQ

59

Type of Network interface

Phy /WirelessPhy

Type of MAC

Mac/802_11

Interface Queue Type

Queue/DropTail /PriQueue

Types of Link Layer

Link Layer

Model of Radio-propagation

Propagation usingTwo Ray

Ground

Routing Protocol

SpRP and M-LEACH

Model of Antenna

Antenna/Omni Antenna

Number of Mobile Nodes

76

Topography X dimension

2800

Topography Y dimension

2800

Time of Simulation End

50

Initial Energy (Joules)

100

Type of Network

Movable

Connection Pattern

Random

Size of Packet

Standard(512 bytes)

Types of Connection

CBR

NS-2 Parameters

Value

Types of Channel

Wireless Channel

Max Packet in IFQ

59

Type of Network interface

Phy /WirelessPhy

Type of MAC

Mac/802_11

Interface Queue Type

Queue/DropTail /PriQueue

Types of Link Layer

Link Layer

Model of Radio-propagation

Propagation usingTwo Ray

Ground

Routing Protocol

SpRP and M-LEACH

Model of Antenna

Antenna/Omni Antenna

Number of Mobile Nodes

76

Topography X dimension

2800

Topography Y dimension

2800

Time of Simulation End

50

Initial Energy (Joules)

100

Type of Network

Movable

Connection Pattern

Random

Size of Packet

Standard(512 bytes)

Types of Connection

CBR

200

0

Fig.10: M-LEACH versus SpRP

M-LEACH

SpRP

Table III: M-LEACH versus SpRP

Performance Metrics

M-LEACH

SpRP

No. of Packet Transmitted

823

1276

No. of Received Packet

743

1219

Ratio of Packet Delivery

90.28

95.53

Average Throughput

44.66

62.29

Average Residual Energy

85.42

97.33

The result generated for LEACH and SpRP protocol from the simulator trace file is shown in Table III. The overall number of packets sent by source node and total number of packets received by end (destination) node and is obtained from NS-2.35 trace file. Packet Delivery Ratio (PDR) is performed with the ratio of reception of packets to

packet sent. The PDR calculated for SpRP is better than LEACH protocol with simulation parameters as shown in

CONCLUSION

There is necessity to design and develop energy efficient routing algorithms which self configures power- saving scheme to improve energy efficiency and to maintain

high geographical area coverage in WSNs. SpRP architecture mainly specifically focuses on network topology formation, selection of spherical routing path and optimal routing. WSNs are divided into multi levels of angular spherical curve: 1-tier and n number of tiers. Each tier forms a spherical cluster up to n number of spherical route for scalable WSN network, which combined together, is called

N-tier SpRP. Simulation reveals that the protocol SpRP achieves better energy balance and network coverage than M- LEACH. The conclusion from the analysis of results is that

SpRP protocol achieves better optimized performance compare to popular wireless sensor network M-LEACH protocol. The proposed work result outcomes from the performance metrics can adds extra life time in a WSN to provide better Quality of Service (QoS) along with security for routing applications.

The research future work will focus on extending scalability and security of SpRP protocol. Using proposed work and performances metric analysis the researchers can

investigate further scope for improvement in proposed

routing protocol by overcoming the limitations such as complete network failure due to a node energy exhaust of SpRP, and also packet delivery ratio, Throughput, low packet

drops & optimized power consumption can be further enhanced in highly scalable random mobility network.

REFERENCES

  1. W. R. Heinzelman, A. Chandrakasan, and H. Balakrishnan, Energy efficient communication protocol for wireless micro sensor networks, in Proceedings of the 33rd Annual Hawaii International Conference on System Sciences (HICSS), pp. 1020, January 2000.

  2. S. Lindsey and C. S. Raghavendra, PEGASIS: Power-efficient gathering in sensor information systems, in Proceedings of the IEEE Aerospace, vol. 3, pp. 11251130, 2002.

  3. Manjeshwar, D.P. Agrawal, TEEN: a protocol for enhanced efficiency in wireless sensor networks, in Proceedings of the 1st International Workshop on Parallel and Distributed Computing Issues in Wireless Networks and Mobile Computing, San Francisco, CA, April 2001.

  4. Manjeshwar and D. P. Agrawal, APTEEN: a hybrid protocol for efficient routing and comprehensive information retrieval in wireless sensor networks, in Proceedings of the 2nd International Workshop on Parallel and Distributed Computing Issues in Wireless Networks and Mobile computing, pp. 195202, April 2002.

  5. Ossama Younis and Sonia Fahmy, HEED: A hybrid, Energy- efficient, Distributed Clustering Approach for Ad-hoc Networks, in IEEE Transactions on Mobile Computing, vol. 3, no. 4, pp. 366-369, Oct-Dec 2004.

  6. T.P. Sharma, R.C. Joshi, Manoj Misra, GBDD: Grid Based Data Dissemination in Wireless Sensor Networks, In Proc. 16th International Conference on Advanced Computing and Communications (ADCOM 2008), Chennai, India, 2008, pp. 234- 240.

  7. Jamal N. Al-Karaki Raza Ul-Mustafa Ahmed E. Kamal, Data Aggregation and Routing in Wireless Sensor Networks: Optimal And Heuristic Algorithms, Computer Networks, Volume 53, Issue 7, Pages 945960, 13 May 2009.

  8. Drago I. Scleanu, Drago M. Ofrim, Rodica Stoian, Vasile Lzrescu, Increasing lifetime in grid wireless sensor networks through routing algorithm and data aggregation techniques, International Journal Of Communications, Issue 4, Volume 5, 2011.

  9. Neng-Chung Wang, Yung-Kuei Chiang, Chih-Hung Hsieh, and Young-Long Chen, Grid-Based Data Aggregation for Wireless Sensor Networks, Journal of Advances in Computer Networks, Vol. 1, No. 4, December 2013.

  10. Yung-Kuei Chiang, Neng-Chung Wang and Chih-Hung Hsieh, A Cycle-Based Data Aggregation Scheme for Grid-Based Wireless Sensor Networks, Sensors 2014, 8447-8464; doi:10.3390/s140508447.

  11. F. Ye, H. Luo, J. Cheng, S. Lu, and L. Zhang, A two-tier data dissemination model for large-scale wireless sensor networks, in MobiCom02:Proceedings of the 8th Annual International Conference on Mobile Computing and Networking, (Atlanta, USA), pp. 148159, ACM, September 2002.

  12. Ameer Ahmed Abbasi and Mohamed Younis, A survey on clustering algorithms for wireless sensor networks Computer Communications 30 (2007) 28262841(Available online: www.elsevier.com/locate/comcom)

  13. Ananthram Swami et al., Wireless Sensor Networks: Signal Processing and Communication Perspectives, John Wiley, 2007.

  14. Feng ZHAO, Leonidas GUIBAS, Wireless Sensor Networks, Elsevier

    Inc. 2004.

  15. Yang Sun, Guangbin Fan, Shigang Chen, Spiral based data dissemination in sensor networks, International Journal of Ad Hoc and Ubiquitous Computing, Volume 2, Issue 1/2, December 2006, Page 46-57.

  16. Bassel Arafh, Khaled Day, Abderezak Touzene, Nasser Alzeidi, Multipath Grid-Based Enabled Geographic Routing for Wireless Sensor Networks, Wireless Sensor Network-Scientific Research, 6, 265-280. http://dx.doi.org/10.4236/wsn.2014.612026.

  17. Xuxun Liu, A Survey on Clustering Routing Protocols in Wireless Sensor Networks, Sensors 2012, 12, 11113-11153; doi: 10.3390/s120811113.

  18. Yuan-Po Chi, Hsung-Pin Chang, An energy-aware grid-based routing scheme for wireless sensor networks, Telecommun Syst (2013) 54:405415, DOI 10.1007/s11235-013-9742-x, pp.405-415, 19 July 2013.

  19. Ja Won Ko and Yoon-Hwa Choi, A Grid-Based Distributed Event Detection Scheme for Wireless Sensor Networks, Sensors 2011, 11, 10048-10062; doi: 10.3390/s111110048, 25 October 2011.

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