TOP 10 Wireless Sensor Research Articles

TOP 10 WIRELESS SENSOR NETWORKS PAPERS: RECOMMENDED READING – NETWORK RESEARCH

  http://airccse.org/top10/wireless_sensor_networks.html

Citation Count – 56

Wireless Sensor Networks Localization Algorithms: A Comprehensive Survey

Asma Mesmoudi , Mohammed Feham , Nabila Labraoui

STIC Laboratory, Departemet of telecommunication,University of Tlemcen, Algeria

ABSTRACT

Wireless sensor networks (WSNs) have recently gained a lot of attention by scientific community. Small and inexpensive devices with low energy consumption and limited computing resources are increasingly being adopted in different application scenarios including environmental monitoring, target tracking and biomedical health monitoring. In many such applications, node localization is inherently one of the system parameters. Localization process is necessary to report the origin of events, routing and to answer questions on the network coverage ,assist group querying of sensors. In general, localization schemes are classified into two broad categories: range-based and range-free. However, it is difficult to classify hybrid solutions as range-based or range-free. In this paper we make this classification easy, where range-based schemes and range-free schemes are divided into two types: fully schemes and hybrid schemes. Moreover, we compare the most relevant localization algorithms and discuss the future research directions for wireless sensor networks localization schemes.

KEYWORDS

Localization, WSN, anchor node, range-based methods, range-free methods, hybrid-based methods.

For More Details : http://airccse.org/journal/cnc/5613cnc03.pdf

Volume Link : http://airccse.org/journal/ijc2013.html

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Citation Count – 49

Towards Internet of Things (IOTS): Integration of Wireless Sensor Network to Cloud Services for Data Collection and Sharing

Rajeev Piyare and Seong Ro Lee

Department of Information Electronics Engineering, Mokpo National University, 534- 729, South Korea

ABSTRACT

Cloud computing provides great benefits for applications hosted on the Web that also have special computational and storage requirements. This paper proposes an extensible and flexible architecture for integrating Wireless Sensor Networks with the Cloud. We have used REST based Web services as an interoperable application layer that can be directly integrated into other application domains for remote monitoring such as e-health care services, smart homes, or even vehicular area networks (VAN). For proof of concept, we have implemented a REST based Web services on an IP based low power WSN test bed, which enables data access from anywhere. The alert feature has also been implemented to notify users via email or tweets for monitoring data when they exceed values and events of interest.

KEYWORDS

Internet of Things, Cloud computing, REST, Wireless Sensor Network, XBee

For More Details :  http://airccse.org/journal/cnc/5513cnc05.pdf

Volume Link : http://airccse.org/journal/ijc2013.html

REFERENCES

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Citation Count – 21

A Reliable and Energy Efficient Transport Protocol for Wireless Sensor Networks

Kamal Kumar Sharma1 , Ram Bahadur Patel2 , Harbhajan Singh3

1Department of Electronics and Communication Engineering, RDJ Faculty of Engineering Dist Mohali Punjab, INDIA
2Department of Computer Engineering, MIT Deemed University, Laxamngarh Rajasthan INDIA
3Department of Electronics and Comm Engineering, SSIET, Derabassi, Punjab INDIA

ABSTRACT

In wireless sensor networks (WSN), an ideal transport layer needs to support reliable message delivery and provide congestion control in an efficient manner in order to extend the lifetime of a WSN. The main use of transport protocol in WSN is to overcome the congestion and the reliability with energy efficiency. In this paper, we develop a reliable and energy efficient transport protocol (REETP), which mainly focuses on the reliability and energy efficiency. Our proposed protocol consist of an Efficient Node Selection Algorithm to determine a set of efficient nodes called E-Nodes which form a near optimal coverage set with largest area and highest residual energy level. The key idea of REETP is to transfer encoded packets using LT codes from the source to the sink block by block and each block is forwarded to an E-node. After receiving encoded packets, the E-node tries to reconstruct the original data packets and it encodes the original data packets again and relays them to the next E-node until it reaches the sink. By simulation results, we show that our proposed protocol has more packet delivery ratio with reduced packet loss and energy consumption.

KEYWORDS

Wireless sensor networks, Congestion, Contention, Energy Efficient, Transmission rate, Data flow

For More Details : http://airccse.org/journal/cnc/0910ijcnc06.pdf

Volume Link : http://airccse.org/journal/ijc2010.html

REFERENCES

[1] Paulo Rogerio Pereira, Antonio Grilo, Francisco Rocha, Mario Serafim Nunes, Augusto Casaca, Claude Chaudet, Peter Almström and Mikael Johansson, “End-To-End Reliability in Wireless Sensor Networks: Survey and Research Challenges”, Euro FGI Workshop on IP QoS and Traffic Control, 2007.

[2] Sandip Dalvi, Anirudha Sahoo and Ashutosh Deo, “A MAC-aware Energy Efficient Reliable Transport Protocol for Wireless Sensor Networks”, In the Proceedings of the IEEE conference on Wireless Communications & Networking Conference, 2009.

[3] Chonggang Wang, Kazem Sohraby, Bo Li and Weiwen Tang, “Issues of Transport Control Protocols for Wireless Sensor Networks”, In the Proceedings of International Conference on Communications, Circuits and Systems (ICCCAS), 2005.

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[8] Yangfan Zhou, Michael R. Lyu, Jiangchuan Liu and Hui Wang, “PORT: A Price-Oriented Reliable Transport Protocol for Wireless Sensor Networks”, Proceedings of the 16th IEEE International Symposium on Software Reliability Engineering, 2005.

[9] Chieh-Yih Wan, Andrew T. Campbell and Lakshman Krishnamurthy, “PSFQ: A Reliable Transport Protocol for Wireless Sensor Networks”, In the Proceedings of the 1st ACM international workshop on Wireless sensor networks and applications, 2002.

[10] Fred Stann and John Heidemann, “RMST: Reliable Data Transport in Sensor Networks”, In the 1st IEEE International Workshop on Sensor Net Protocols and Applications (SNPA), 2003.

[11] Yogesh Sankarasubramaniam, Ozgur B. Akan and Ian F. Akyildiz, “ESRT: EventtoSink Reliable Transport in Wireless Sensor Networks”, Proceedings of 4th ACM International symposium on Mobile ad hoc networking & computing, 2003.

[12] Nurcan Tezcan and Wenye Wang, “ART: An Asymmetric and Reliable Transport Mechanism for Wireless Sensor Networks”, International Journal of Sensor Networks, 2007.

[13] Yao-Nan Lien, “Hop-by-Hop TCP for Sensor Networks”, International Journal of Computer Networks & Communications (IJCNC), 2009

[14] Sunil Kumar, Zhenhua Feng, Fei Hu and Yang Xiao, “E2SRT: enhanced event-to-sink reliable transport for wireless sensor networks”, Wireless Communications and Mobile Computing, 2008.

[15] Damayanti Datta and Sukhamay Kundu, “An Application-Specific Reliable Data Transfer Protocol in Wireless Sensor Networks”, Journal of Networks, 2008

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[17] Dunkels, A., Alonso, J. and Voigt, T., “Making TCP/IP Viable for Wireless Sensor Networks”. First European Workshop on Wireless Sensor Networks (EWSN’04), work-in-progress session, Berlin, Germany 2004.

[18] N. Riga , I. Matta , A. Medina , C. Partridge , J. Redi, “An energy-conscious transport protocol for multi-hop wireless networks”, Proceedings of the 2007 ACM CoNEXT conference, New Work, 2007.

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Citation Count – 21

Concepts and Evolution of Research in the Field Of Wireless Sensor Networks

Ado Adamou ABBA ARI 1, 3 *, Abdelhak GUEROUI , Nabila LABRAOUI 2
and Blaise Omer YENKE 3

1 PRISM, University of Versailles St-Quentin-en-Yvelines, France
2 STIC, University of Tlemcen, Algeria
3 LASE, University of Ngaoundere, Cameroon

ABSTRACT

The field of Wireless Sensor Networks (WSNs) is experiencing a resurgence of interest and a continuous evolution in the scientific and industrial community. The use of this particular type of ad hoc network is becoming increasingly important in many contexts, regardless of geographical position and so, according to a set of possible application. WSNs offer interesting low cost and easily deployable solutions to perform a remote real time monitoring, target tracking and recognition of physical phenomenon. The uses of these sensors organized into a network continue to reveal a set of research questions according to particularities target applications. Despite difficulties introduced by sensor resources constraints, research contributions in this field are growing day by day. In this paper, we present a comprehensive review of most recent literature of WSNs and outline open research issues in this field.

KEYWORDS

WSNs, protocols, sensor, applications, routing, services, survey, bio-inspired.

For More Details :  http://airccse.org/journal/cnc/7115cnc06.pdf

Volume Link : http://airccse.org/journal/ijc2015.html

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Citation Count – 20

H-MAC : A Hybrid MAC Protocol for Wireless Sensor Networks

Mehta and K.S. Kwak

UWB Wireless Communications Research Center, Inha University
Incheon, 402-751, Korea

ABSTRACT

In this paper, we propose a hybrid medium access control protocol (H-MAC) for wireless sensor networks. It is based on the IEEE 802.11’s power saving mechanism (PSM) and slotted aloha, and utilizes multiple slots dynamically to improve performance. Existing MAC protocols for sensor networks reduce energy consumptions by introducing variation in an active/sleep mechanism. But they may not provide energy efficiency in varying traffic conditions as well as they did not address Quality of Service (QoS) issues. H-MAC, the propose MAC protocol maintains energy efficiency as well as QoS issues like latency, throughput, and channel utilization. Our numerical results show that H-MAC has significant improvements in QoS parameters than the existing MAC protocols for sensor networks while consuming comparable amount of energy.

KEYWORDS

Sensor networks, MAC protocol, energy efficiency.

For More Details : http://airccse.org/journal/cnc/10108.pdf

Volume  Link : http://airccse.org/journal/ijc2010.html

REFERENCES

[1] I.F. Akayildiz, W. Su, S. Yogesh, & E. Cayirci, (2008) ” A Survey on Sensor Networks”, IEEE Communication, August, pp 102-114

[2] W. Ye, J. Heidemann, & D. Estrin , (2000) “ An Energy- Efficient MAC Protocol for wireless Sensor Networks,” in proceeding of INFOCOM 2002, New York, June , pp.1567-1576.

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[6] IEEE 802.11 Working Group, (1999) “Wireless LAN Medium Access Control (MAC) and Physical Layer (PHY) specifications”.

[7] S.Mehta & K.S. Kwak, (2008) “H-MAC: A Hybrid MAC Protocol for Wireless Sensor Networks,” in proceeding of IEEE Seoul Chapter Paper Contest, December, pp:705/706.

[8] G.Bianchi, “ Performance Analysis of IEEE 802.11 distributed coordination function,” IEEE JSAC , Vol.18,no-3, pp.535-547, Mar.2000.

[9] R. Rom and M.Sidi, “Multiple Access Protocols: Performance and Analysis,” Springer-Verlag Publication, 1989.

Citation Count – 19

AOM : An Efficient Approach to Restore Actor-Actor Connectivity in Wireless Sensor and Actor Networks

Azadeh Zamanifar, Omid Kashefi and Mohsen Sharifi

Computer Engineering Department, Iran University of Science and Technology,
Tehran, Iran

ABSTRACT

Wireless sensor and actor networks (WSANs) consist of powerful actors and resource constraint sensors that are linked together in wireless networks. They mostly rely on actors to make proper decisions and perform desired coordination to achieve the goals of the entire network. They are usually deployed in critical applications and actor-actor network connectivity is thus vital to their effective utilization. Since WSAN applications are mostly deployed in harsh environments, actor nodes may fail and so partition their network. We propose a comparatively more efficient distributed approach, nicknamed AOM, to restore actor-actor connectivity upon the failure of any actor. We identify critical actors by combining the result of determining critical actors using the Stojmenovich’s method with the connectivity dominating set (CDS) of the network. This hybrid method of detecting critical actors helps in detecting critical nodes and candidate replacement actors more precisely while minimizing the total number of required messages for network restoration. The failure handling of actors is done in a proactive manner. Our proposed method minimizes both the restoration time of network and the total number of actor movements. When a failed actor is a critical node, actors in its neighborhood are relocated in a coordinated way to reconnect the actor network. The superiority of our approach compared to other works is shown by simulative experiments measuring two important parameters to WSANS, namely, the total number of transmitted messages and the total number of actor movements during actor-actor network reconnection process.

KEYWORDS

Wireless Sensor and Actor Network; Network Restoration; Actor Connectivity; Cut Vertex; Connectivity Dominating Set (CDS).

For More Details http://airccse.org/journal/cnc/04095.pdf

Volume Link :http://airccse.org/journal/j2current.html

REFERENCES

[1] Akyildiz, F. and Kasimoglu, I. H. (2004) Wireless sensor and actor networks: research challenges. Elsevier Ad Hoc Network Journal. 2 351-367.

[2] Akkaya, K., Thimmapuram, A., Senel, F. and Uludag, S. (2008) Distributed recovery of actor failures in wireless sensor and actor networks. Proceedings of the IEEE Wireless Communications and Networking Conference.

[3] Jorgic, M., Stojmenovic, I., Hauspie, M. and Simplot-ryl, D. (2004) Localized algorithms for detection of critical nodes and links for connectivity in ad hoc networks. Proceedings of the 3rd Annual IFIP Mediterranean Ad Hoc Networking Workshop pp. 360-371.

[4] Dai, F. and Wu, J. (2004) An Extended Localized Algorithm for Connected Dominating Set Formation in Ad Hoc Wireless Networks. IEEE Transaction on Parallel and Distributed Systems. 15(10) 908-920.

[5] Abbasi, A. A., Akkaya, K. and Younis, M. (2007) A Distributed Connectivity Restoration Algorithm in Wireless Sensor and Actor Networks. Proceedings of the 32nd IEEE Conference on Local Computer Networks IEEE Computer Society.

[6] Ozaki, K., Watanabe, K., Itaya, S., Hayashibara, N., Enokido, T. and Takizawa, M. (2006) A FaultTolerant Model ofWireless Sensor-Actor Network. Proceedings of the 9th IEEE International Symposium on Object and Component-Oriented Real-Time Distributed Computing IEEE Computer Society.

[7] Wu, J., Yang, S. and Cardei, M. (2008) On Maintaining Sensor-Actor Connectivity in Wireless Sensor and Actor Networks. Proceedings of the 27th Conference on Computer Communications,IEEE INFOCOM pp. 286-290.

[8] Akkaya, K. and Younis, M. (2007) C2AP: Coverage-aware and Connectivity-constrained Actor Positioning in Wireless Sensor and Actor Networks. Proceedings of the IEEE Internationa Performance, Computing, and Communications Conference pp. 281-288.

[9] Das, S., Liu, H., Kamath, A., Nayak, A. and Stojmenović, I. (2007) Ttile., Wireless Sensor and Actor Networks.

[10] Basu, P., Redi, J., Technol, B. and Cambridge, M. (2004) Movement control algorithms for realization of fault-tolerant ad hoc robot networks. IEEE network. 18(4) 36-44.

[11] Li, X., Santoro, N. and Stojmenovic, I. (2007) Ttile., Ubiquitous Intelligence and Computing.

[12] Wang, G., Cao, G., Porta, T. L. and Zhang, W. (2005) Sensor relocation in mobile sensor networks. Proceeding of the 24th Annual IEEE Conference on Computer Communications.

[13] Goyal, D. and J. Caffery, J. (2002) Partitioning Avoidance in Mobile Ad Hoc Networks Using Network Survivability Concepts. Proceedings of the Seventh International Symposium on Computers and Communications IEEE Computer Society.

[14] Seada, K. and Helmy, A. (2004) Efficient geocasting with perfect delivery in wireless networks. Proceedings of the IEEE Wireless Communications and Networking Conference.

[15] Baldwin, P., Kohli, S., Lee, E. A., Liu, X. and Zhao, Y. (2004) Modeling of sensor nets in Ptolemy II. Proceedings of the 3rd international symposium on Information processing in sensor networks ACM.

Citation Count – 10

Empirical Examination of Mobile Ad Hoc Routing Protocols on Wireless Sensor Networks

Zhongwei Zhangand Hong Zhou2

Department of Mathematics and Computing, University of Southern Queensland, Toowoomba, QLD 4350
2 Department of Electronic Engineering, University of Southern Queensland,
Toowoomba, QLD 4350

ABSTRACT

Wireless sensor networks (WSNs) have great potential of being deployed in many places where traditional wired or wireless networks are not feasible. But they have also many new challenges more than other wireless networks. These challenges include the design of embedded intelligent sensors and wireless networking technology, ie. routing protocols and network security. WSNs also have some constraints such as sensor nodes failure which render WSN unavailable. The routing protocol in the sensor networks plays a critical role. They influence the performance of the WSNs and have significant impact on the security and the availability of WSNs. Wireless sensor networks (WSNs) have been regarded as an incarnation of Ad Hoc Networks for a specific application. Since a WSN consists of potentially hundreds of low cost, small size and battery powered sensor nodes, it has more potentials than a MANET to be deployed in many emerging areas. However, they also raised many new challenges, and these challenges include the design of embedded sensors and wireless networking technology, ie. routing protocols and network security. Many ad hoc routing protocols such as AODV, DSR, DSDR, TORA and OLSR, which have been developed particularly for the mobile wireless ad hoc networks (MANETs), performed satisfactorily on MANETs. Research has shown that these ad-hoc routing protocols work well for MANETs with different characteristics and requirements. In this paper, we investigate how well these ad-hoc routing protocols work on wireless sensor networks (WSNs). We focus on their performances in terms of average end-to end delay, packet delivery ratio and routing overheads.

KEYWORDS

Wireless technology, Sensor nodes, Dynamic routing, Throughput, Wireless Network, End-to-End delay

For More Details :  http://airccse.org/journal/cnc/04096.pdf

Volume Link :  http://airccse.org/journal/j2current.html

REFERENCES

[1] Ian F. Akyildiz, Weilian Su, Yogesh Sankarasubramaniam, and E. Cayirci (2002). A survey on sensor networks. IEEE Communications Magazine, Aug 2002. pp 102-114.

[2] H. Chan and A. Perrig, (2003) Security and privacy in sensor networks. IEEE Computer, Oct 2003. pp 103-105.

[3] Carla Fabiana Chiasserini and Michele Garetto, (2004) Modeling the performance of wireless sensor networks. IEEE INFOCOM, Hong Kong, March 7-11, 2004.

[4] Marco Conti and Silvia Giordano, (2007) Multihop Ad Hoc Networking: The Reality, IEEE Communication Magazine, April 2007. pp 88-95.

[5] Ian Downard, (2004) Simulating sensor network in ns-2. NRL Formal Report 5522.

[6] Deborah Estrin, David Cullar, Kris Pister and Gaurav Sukhatme, (2002) Connecting the Physical World with Pervasive Networks, Pervasive Computing, Jan 2002. pp 59-69.

[7] Qiangfeng Jiang and D. Manivannan, (2004) Routing Protocols for Sensor Networks, Consumer Communications and Networking Conference, First IEEE Volume Issue, Jan 2004. pp 93-98.

[8] Anthony D. Wood and John A. Stankovic (2002) Denial of Service in Sensor Networks, IEEE Computer, Oct 2002. pp54-62.

[9] Yunjiao Xue, Ho Sung Lee, Ming Yang, Priantha Kumarawadu, Hamada H. Ghenniwa and Weiming Shen (2007) Performance Evaluation of NS2 Simulator for Wireless Sensor Networks, IEEE, 2007. pp 1372-1375.

[10] H. Zhou, J. Lu, Z. Zhang, H. Ali, and C. Won (2007) Application and performance of extended TTDD’s in large-scale wireless sensor networks. MSN 2007, LNVC 4864, Dec. 2007. pp 135- 142.

Citation Count – 10

A Cross-Layer Approach for Minimizing Interference and Latency of Medium Access in Wireless Sensor Networks

Behnam Dezfouli1 , Marjan Radi2 , Shukor Abd Razak3

Faculty of Computer Science and Information Systems, Universiti Teknologi Malaysia (UTM), Malaysia

ABSTRACT

In low power wireless sensor networks, MAC protocols usually employ periodic sleep/wake schedule to reduce idle listening time. Even though this mechanism is simple and efficient, it results in high end-to end latency and low throughput. On the other hand, the previously proposed CSMA/CA based MAC protocols have tried to reduce inter-node interference at the cost of increased latency and lower network capacity. In this paper we propose IAMAC, a CSMA/CA sleep/wake MAC protocol that minimizes inter node interference, while also reduces per-hop delay through cross-layer interactions with the network layer. Furthermore, we show that IAMAC can be integrated into the SP architecture to perform its inter layer interactions. Through simulation, we have extensively evaluated the performance of IAMAC in terms of different performance metrics. Simulation results confirm that IAMAC reduces energy consumption per node and leads to higher network lifetime compared to S-MAC and Adaptive S-MAC, while it also provides lower latency than S-MAC. Throughout our evaluations we have considered IAMAC in conjunction with two error recovery methods, i.e., ARQ and Seda. It is shown that using Seda as the error recovery mechanism of IAMAC results in higher throughput and lifetime compared to ARQ.

KEYWORDS

Wireless Sensor Networks, MAC, IAMAC, Tree-Based Routing, Cross-Layer Optimization, Interference.

For More Details : http://airccse.org/journal/cnc/0710ijcnc11.pdf

Volume Link: http://airccse.org/journal/ijc2010.html

REFERENCES

[1] M. Z. Zamalloa and B. Krishnamachari, “An analysis of unreliability and asymmetry in low-power wireless links,” ACM Trans. Sen. Netw., vol. 3, 2007, p. 7.

[2] A. Woo, T. Tong, and D. Culler, “Taming the underlying challenges of reliable multihop routing in sensor networks,” Proceedings of the 1st international conference on Embedded networked sensor systems, Los Angeles, California, USA: ACM, 2003, pp. 14-27.

[3] Q. Cao, T. He, L. Fang, T. Abdelzaher, J. Stankovic, and S. Son, “Efficiency centric communication model for wireless sensor networks,” Proceedings IEEE INFOCOM 2006. 25TH IEEE International Conference on Computer Communications, IEEE, 2006, pp. 1-12.

[4] A. Cerpa, J. Wong, L. Kuang, M. Potkonjak, and D. Estrin, “Statistical model of lossy links in wireless sensor networks,” Proceedings of the 4th international symposium on information processing in sensor networks, IEEE Press, 2005, p. 11.

[5] D. S. Couto, D. Aguayo, J. Bicket, and R. Morris, “A high-throughput path metric for multi-hop wireless routing,” Wirel. Netw., vol. 11, 2005, pp. 419-434.

[6] J. Heidemann and D. Estrin, “An energy-efficient MAC protocol for wireless sensor networks,” IEEE INFOCOM, New York, USA: 2002, pp. 1567-1576.

[7] T. van Dam and K. Langendoen, “An adaptive energy-efficient MAC protocol for wireless sensor networks,” Proceedings of the first international conference on Embedded networked sensor systems – SenSys ’03, New York, New York, USA: ACM Press, 2003, p. 171.

[8] W. Ye, J. Heidemann, and D. Estrin, “Medium access control with coordinated adaptive sleeping for wireless sensor networks,” IEEE/ACM Trans. Netw., vol. 12, 2004, pp. 493-506.

[9] J. Polastre, J. Hill, and D. Culler, “Versatile low power media access for wireless sensor networks,” Proceedings of the 2nd international conference on Embedded networked sensor systems – SenSys ’04, New York, New York, USA: ACM Press, 2004, p. 95.

[10] M. Sichitiu, “Cross-layer scheduling for power efficiency in wireless sensor networks,” IEEE INFOCOM 2004, IEEE, 2004, pp. 1740-1750.

[11] V. Kawadia and P. R. Kumar, “A cautionary perspective on cross-layer design,” Wireless Communications, IEEE, vol. 12, 2005, pp. 3-11.

[12] V. Srivastava and M. Motani, “Cross-layer design: A survey and the road ahead,” Communications Magazine, IEEE, vol. 43, 2005, p. 112,119.

[13] J. Polastre, J. Hui, P. Levis, J. Zhao, D. Culler, S. Shenker, and I. Stoica, “A unifying link abstraction for wireless sensor networks,” Proceedings of the 3rd international conference on Embedded networked sensor systems – SenSys ’05, New York, USA: ACM Press, 2005, p. 76.

[14] N. Ramanathan, M. Yarvis, J. Chhabra, N. Kushalnagar, L. Krishnamurthy, and D. Estrin, “A stream-oriented power management protocol for low duty cycle sensor network applications,” Proceedings of the 2nd IEEE workshop on Embedded Networked Sensors, IEEE Computer Society, 2005, pp. 53-61.

[15] J. van Greunen and J. Rabaey, “Lightweight time synchronization for sensor networks,” Proceedings of the 2nd ACM international conference on wireless sensor networks and applications – WSNA ’03, New York, USA: ACM Press, 2003, p. 11.

[16] J. Elson, L. Girod, and D. Estrin, “Fine-grained network time synchronization using reference broadcasts,” ACM SIGOPS Operating Systems Review, vol. 36, 2002, p. 147.

[17] Y. Zhao, M. Ma, C. Miao, and T. Nguyen, “An energy-efficient and low-latency MAC protocol with Adaptive Scheduling for multi-hop wireless sensor networks,” Computer Communications, In Press, 2010.

[18] R. K. Ganti, P. Jayachandran, H. Luo, and T.F. Abdelzaher, “Datalink streaming in wireless sensor networks,” Proceedings of the 4th international conference on Embedded networked sensor systems – SenSys ’06, New York, USA: ACM Press, 2006, p. 209.

[19] T. Melodia, M. C. Vuran, and D. Pompili, “The state of the art in cross-layer design for wireless sensor networks,” Proceedings of EuroNGI Workshops on Wireless and Mobility, Springer Lecture Notes on Computer Science, LNCS 388, Como, Italy: 2005.

Citation Count – 08

Performance Analysis of an Improved Graded Precision Localization Algorithm for Wireless Sensor Networks

Sanat Sarangi and Subrat Kar

Bharti School of Telecommunication Technology and Management, IIT Delhi, Hauz Khas, New Delhi, India – 110 016

ABSTRACT

In this paper an improved version of the graded precision localization algorithm GRADELOC, called IGRADELOC is proposed. The performance of GRADELOC is dependent on the regions formed by the overlapping radio ranges of the nodes of the underlying sensor network. A different region pattern could significantly alter the nature and precision of localization. In IGRADELOC, two improvements are suggested. Firstly, modifications are proposed in the radio range of the fixed-grid nodes, keeping in mind the actual radio range of commonly available nodes, to allow for routing through them. Routing is not addressed by GRADELOC, but is of prime importance to the deployment of any adhoc network, especially sensor networks. A theoretical model expressing the radio range in terms of the cell dimensions of the grid infrastructure is proposed, to help in carrying out a deployment plan which achieves the desirable precision of coarse-grained localization. Secondly, in GRADELOC it is observed that fine-grained localization does not achieve significant performance benefits over coarse-grained localization. In IGRADELOC, this factor is addressed with the introduction of a parameter that could be used to improve and fine-tune the precision of fine-grained localization.

KEYWORDS

Wireless sensor networks, Localization, Centroid, TDOA, Fixed-grid.

For More Details: http://airccse.org/journal/cnc/0710ijcnc13.pdf

Volume Link : http://airccse.org/journal/ijc2010.html

REFERENCES

[1] J. W. Kim, H. J. Jang, D. Hwang, and C. Park, A step, stride and heading determination for the pedestrian navigation system, Journal of Global Positioning Systems 3 (2004), no. 1-2, 273–279.

[2] L. Klingbeil and T. Wark, A wireless sensor network for real-time indoor localization and motion monitoring, Proc. of 7th Intl Conf. on Inf. Proc. in Sensor Networks, 2008, pp. 39–50.

[3] D. Ping, Yongjun, X., and L. Xiaowei, A robust location algorithm with biased extended kalman filtering of tdoa data for wireless sensor networks, Proc. of Intl Conf. on Wireless Comm., Networking & Mobile Computing (WCNM’05) (Wuhan, China), vol. 2, 2005, pp. 883–886.

[4] S. Sarangi and S. Kar, A novel algorithm for graded precision localization in wireless sensor networks, Proc. of 1st Intl. Conf. on Networks and Comm. (NETCOM’09) (Chennai, India), pp. 18–22, 2009.

Citation Count – 08

Determination of Optimal Number of Clusters in Wireless Sensor Networks

Ravi Tandon

Department of Computer Science and Engineering, Indian Institute of Technology Guwahati, India.

ABSTRACT

Prolonged network lifetime, scalability and efficient load balancing are essential for optimal performance of a wireless sensor network. Clustering provides an effective way of extending the lifetime of a sensor network. Clustering is the process that divides sensor networks into smaller localized group (called clusters) of members with a cluster head. Clustering protocols need to elect optimal number of  clusters in hierarchically structured wireless sensor networks. Any clustering scheme that elects clusters uniformly (irrespective of the distance from Base Station) incurs excessive energy usage on clusters proximal and distant to Base Station. In single hop networks a gradual increment in the energy depletion rate is observed as the distance from the cluster head increases[17]. This work focuses on the analysis of wasteful energy consumption within a uniform cluster head election model (EPEM) and provides an analytical solution to reduce the overall consumption of energy usage amongst the clusters elected in a wireless sensor network. A circular model of sensor network is considered, where the sensor nodes are deployed around a centrally located Base Station. The sensor network is divided into several concentric rings centred at the Base Station. A model, Unequal Probability Election Model (UEPEM), which elects cluster heads non-uniformly is proposed. The probability of cluster head election depends on the distance from the Base Station. UEPEM reduces the overall energy usage by about 21% over EPEM. The performance of UEPEM improves as the number of rings is increased.

KEYWORDS

Wireless sensor networks, Ad-hoc networks, clustering.

For More Details :   http://airccse.org/journal/cnc/0712cnc15.pdf

Volume Link : http://airccse.org/journal/ijc2012.html

REFERENCES

[1] Chatterjee, M., Das, S., & Turgut, D. (2002). WCA: A weighted clustering algorithm for mobile ad hoc networks. Cluster Computing , 5 (2), 193-204.

[2] Depedri, A., Zanella, A., & Verdone, R. (2003). An energy efficient protocol for wireless sensor networks. Proceeding of the AINS 2003. Menlo Park .

[3] Dietrich, I., & Dressler, F. (Feburary 2009). On the Lifetime of Wireless Sensor Networks. ACM Transactions Sensor Networks, 5, pp. 5:1–5:39.  International Journal of Computer Networks & Communications (IJCNC) Vol.4, No.4, July 2012 249

[4] Ettus, M. (1998). System capacity, latency, and power consumption in multihop-routed SSCDMA wireless networks. Radio and Wireless Conference, 1998. RAWCON 98. 1998 IEEE (pp. 55-58). IEEE press.

[5] Heinzelman, W., MA Chandrakasan, A., & Balakrishnan, H. (2002). An application-specific protocol architecture for wireless microsensor networks. IEEE Transactions on Wireless Communications , 1 (4), 660-670.

[6] Hill, J., Szewczyk, R., Woo, A., Hollar, S., Culler, D., & Pister, K. (2000). System architecture directions for networked sensors. ACM Sigplan Notices , 35 (11), 93-104.

[7] Lee, S., Yoo, J., & Chung, T. (2004). Distance-based energy efficient clustering for wireless sensor networks. 29th Annual IEEE International Conference on Local Computer Networks, 2004. , (pp. 567-568).

[8] Li, C., Ye, M., Chen, G., & Wu, J. (2005). An energy-efficient unequal clustering mechanism for wireless sensor networks. IEEE International Conference on Mobile Adhoc and Sensor Systems Conference. IEEE press.

[9] Mhatre, V., & Rosenberg, C. (2004). Design guidelines for wireless sensor networks: communication, clustering and aggregation. Ad Hoc Networks , 2 (1), 45-63.

[10] Mhatre, V., & Rosenberg, C. (2004). Homogeneous vs heterogeneous clustered sensor networks: a comparative study. IEEE International Conference on Communications, 2004. 6, pp. 3646- 651. IEEE press.

[11] Rajagopalan, R., & Varshney, P. K. (2006). Data aggregation techniques in sensor networks: A survey. Communication Surveys and Tutorials, IEEE, 8, pp. 48-63.

[12] Shepard, T. (1996). A channel access scheme for large dense packet radio networks. ACM SIGCOMM Computer Communication Review. 26, pp. 219-230. ACM.

[13] Smaragdakis, G., Matta, I., & Bestavros, A. (August 2004). SEP: A Stable Election Protocol for clustered heterogeneous wireless sensor networks. Second International Workshop on Sensor and Actor Network Protocols and Applications (SANPA 2004).

[14] Soro, S., & Heinzelman, W. (2005). Prolonging the lifetime of wireless sensor networks via unequal clustering. In Parallel and Distributed Processing Symposium, 2005. Proceedings. 19th IEEE International. IEEE press.

[15] Wang, W., Wang, B., Liu, Z., Guo, L., & Xiong, W. (2011). A cluster-based and tree-based power efficient data collection and aggregation protocol for wireless sensor networks. Information Technology Journal , 10, 557-564.

[16] Wu, M. Y., Li, C., Chen, G., & Jie. (2005). An energy efficient clustering scheme in wireless sensor networks. In Proceedings of the IEEE International Performance Computing and Communications Conference (pp. 535-540). IEEE Press.

[17] Wu, X., Chen, G., & Das, S. (2006). On the energy hole problem of nonuniform node distribution in wireless sensor networks. IEEE International Conference on Mobile Adhoc and Sensor Systems (MASS), 2006 (pp. 180-187). IEEE press.

[18] Yi, S., Heo, J., Cho, Y., & Hong, J. (2007). PEACH: Power-efficient and adaptive clustering hierarchy protocol for wireless sensor networks. Computer communications , 30 (14-15), 2842- 2852.

[19] Younis, O., & Fahmy, S. (2004). HEED: A Hybrid, Energy-Efficient, Distributed Clustering Approach for Ad Hoc Sensor Networks. IEEE Transactions on Mobile Computing , 3 (4), 366- 379.

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

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