Most Popular Papers

A Wireless Sensor Network (WSN) normally consists of an exceptionally large number of inexpensive, disposable, robust, small, and low power sensor nodes operational considerately. A Distributed and Scalable Scheduling Access (DSSA) scheme that mitigates in wireless sensor networks handles some mobility with high data loss due to the faults. A virtual grid network in distributed and scalable scheduling access scheme is an effortless method to cluster local sensors but fails in network scalability improvement. Existing, Information Controlled Transmission Power (ICTP) alteration method uses higher transmission powers with additional information than individuals that are less instructive to distribute their object state information with the neighboring nodes. ICTP does not detect faults and outlier sensor nodes in the network and probable safety measures have to be taken against them. To overcome these faulty and energy saving issues, Collaborator Homed Routing (CHR) mechanism is developed in WSN. In CHR, cluster heads aggregate information and relay information to the base station independently for improving system’s transmission power with half amount of energy consuming. Non Cluster Head (NCH) nodes choose a restricted number of objects in the information transmission. Based on the CHR principles, designed and implemented a novel mechanism to handle faulty situations. Using CHR in WSN, cluster head faults are installed to observe the scalability of these mechanisms. Therefore CHR consumes less energy with minimal faults. Experimental results show that proposed routing considerably reduces energy consumption, fault free routing, and reduces the possibility of communication disturbance, network scalability, throughout and link failure ratio is compared to existing method
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Non Cluster Head; Collaborator Homed Routing; Sensor Network; Relay Information; Base Station; Network Scalability; Outlier Sensor Nodes

Chih-Kuang Lin.,, Vladimir I. Zadorozhny., Prashant V. Krishnamurthy, Ho-Hyun Park, and Chan-Gun Lee., “A Distributed and Scalable Time Slot Allocation Protocol for Wireless Sensor Networks,” IEEE Transactions on Mobile Computing , Vol. 10, N. 4, April 2011,pp.505-518.

Tolga Onel, Cem Ersoy, and Hakan Delic¸, “Information Content-Based Sensor Selection and Transmission Power Adjustment for Collaborative Target Tracking,” IEEE Transactions on Mobile Computing , Vol. 8, N. 8, August 2009,pp.1103-1116.

Chi Lin., Guowei Wu., Feng Xia., Mingchu Li., Lin Yao., Zhongyi Pei., “Energy efficient ant colony algorithms for data aggregation in wireless sensor networks,” Journal of Computer and System Sciences., Elsevier journal., 2012, pp.1686-1702.

Octav Chipara., Chenyang Lu., John A. Stankovic., and Catalin-Gruia Roman., “Dynamic Conflict-Free Transmission Scheduling for Sensor Network Queries,” IEEE Transactions on Mobile Computing , Vol. 10, N. 5, May 2011, pp. 734-748.

Liang Liu., Xi Zhang., and Huadong Ma., “Localization-Oriented Coverage in Wireless Camera Sensor Networks,” IEEE Transactions on Wireless Communications, Vol. 10, N. 2,February 2011, pp.484-494.

Pangun Park., Carlo Fischione., Alvise Bonivento., Karl Henrik Johansson, and Alberto L. Sangiovanni-Vincentelli., “Breath: An Adaptive Protocol for Industrial Control Applications Using Wireless Sensor Networks,” IEEE Transactions on Mobile Computing , Vol. 10, N. 6, June 2011, pp.821-838.

Djamel Djenouri., and Ilangko Balasingham., “Traffic-Differentiation-Based Modular QoS Localized Routing for Wireless Sensor Networks,” IEEE Transactions on Mobile Computing , Vol. 10, N. 6, JUNE 2011, pp.797-809.

Koushik Sinha., Bhabani P. Sinha., and Debasish Datta., “An Energy-Efficient Communication Scheme for Wireless Networks: A Redundant Radix-Based Approach,” IEEE Transactions on Wireless Communications, Vol. 10, N. 2, February 2011, pp.550-559.

Javier Matamoros., and Carles Antón-Haro., “Optimal Network Size and Encoding Rate for Wireless Sensor Network-Based Decentralized Estimation under Power and Bandwidth Constraints,” IEEE Transactions on Wireless Communications, Vol. 10, N. 4, April 2011, pp.1121-1131

Wei-Chieh Ke., Bing-Hong Liu., and Ming-Jer Tsai., “Efficient Algorithm for Constructing Minimum Size Wireless Sensor Networks to Fully Cover Critical Square Grids,” IEEE Transactions on Wireless Communications, Vol. 10, N. 4, April 2011, pp.1154-1164.

Marco Gribaudo., Daniele Manini., Alessandro Nordio., and Carla-Fabiana Chiasserini., “Transient Analysis of IEEE 802.15.4 Sensor Networks,” IEEE Transactions on Wireless Communications, Vol. 10, NO.4, April 2011,pp.1165-1175.

Xue Wang., Junjie Ma., Sheng Wang., and Daowei Bi., “Distributed Energy Optimization for Target Tracking in Wireless Sensor Networks,” IEEE Transactions on Mobile Computing , Vol. 9, N. 1, January 2009,pp.73-86.

Yue-Hsun Lin., Shih-Ying Chang., and Hung-Min Sun., “CDAMA: Concealed Data Aggregation Scheme for Multiple Applications in Wireless Sensor Networks,” IEEE Transactions on Knowledge AND Data Engineering, Vol. 25, N. 7, JULY 2013, pp.1471-1483.

Pu Wang., RuiDai., and Ian F. Akyildiz, “A Differential Coding-Based Scheduling Framework for Wireless Multimedia Sensor Networks,” IEEE Transactions on Multimedia, Vol. 15, N. 3, April 2013, pp. 684-697.

Xiaonan Wang., and Huanyan Qian., “Constructing a 6LoWPAN Wireless Sensor Network Based on a Cluster Tree,” IEEE Transactions on Vehicular Technology, Vol. 61, N. 3, March 2012, pp.1398-1405.

Jiguo Yua., Yingying Qia., Guanghui Wangb, Xin Gua., “A cluster-based routing protocol for wireless sensor networks with nonuniform node distribution,” International Journal of Electronics and Communications (AEÜ)., Elsevier Journal., 2012, pp.1-10.

GholamHossein Ekbatanifard., Reza Monsefi., Mohammad H. Yaghmaee M., Seyed Amin Hosseini S., “Queen-MAC: A quorum-based energy-efficient medium access control protocol for wireless sensor networks,” Computer Networks., Elsevier journal, 2012, pp. 2221-2236.

Yuan He., and Mo Li., “COSE: A Query-Centric Framework of Collaborative Heterogeneous Sensor Networks,” IEEE Transactions on Parallel and Distributed Systems, Vol. 23, N. 9, September 2012, pp.1681-1693.

Chien-Ming Chen., Yue-Hsun Lin., Ya-Ching Lin., and Hung-Min Sun., “RCDA: Recoverable Concealed Data Aggregation for Data Integrity in Wireless Sensor Networks,” IEEE Transactions on Parallel and Distributed Systems, Vol. 23, N. 4, April 2012, pp. 727-734.

Yu-Kai Huang., Ai-Chun Pang., Pi-Cheng Hsiu., Weihua Zhuang., and Pangfeng Liu., “Distributed Throughput Optimization for ZigBee Cluster-Tree Networks,” IEEE Transactions on Parallel and Distributed Systems, Vol. 23, N. 3, March 2012, pp. 513-520.

R. Aggarwal, H. Aggarwal, L. Kaur, On Bandwidth Analysis of Fault-tolerant Multistage Interconnection Networks, (2008) International Review on Computers and Software (IRECOS), 3. (2), pp. 199 - 202.

Li, W., Xu, Q., Xu, K., Analysis on the cooperative fault diagnosis method based on the immune evolutionary strategy, (2012) International Review on Computers and Software (IRECOS), 7 (6), pp. 2915-2920.

Shivaprakasha, K.S., Kulkarni, M., Energy efficient routing protocols for wireless sensor networks: A survey, (2011) International Review on Computers and Software (IRECOS), 6 (6), pp. 929-943.

Azimiyan, F., Kheirkhah, E., Jalali, M., Classification of routing protocols in wireless sensor networks, (2012) International Review on Computers and Software (IRECOS), 7 (4), pp. 1614-1623.

Mansouri, H., Benhaddou, S., Medromi, H., Energy security optimization in wireless sensor network based on multi agent system architecture, (2012) International Review on Computers and Software (IRECOS), 7 (2), pp. 518-524.

Kalai Kumar, K., Baburaj, E., Performance analysis of cross layer communication in wireless sensor network to improve throughput and utility maximization, (2013) International Review on Computers and Software (IRECOS), 8 (11), pp. 2634-2641.

Loutfi, A., El Koutbi, M., Impact of mobility and density on a cross-layer architecture for wireless sensor networks, (2013) International Review on Computers and Software (IRECOS), 8 (8), pp. 1793-1800.