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Wireless Personal Communications

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23-08-2019

Semisupervised Classification Based Clustering Approach in WSN for Forest Fire Detection

Authors: Ditipriya Sinha, Rina Kumari, Sudhakar Tripathi

Published in: Wireless Personal Communications | Issue 4/2019

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Abstract

Forest fire is a very considerable problem of ecological system. This paper depicts a novel technique which detects the high active(HA) zone (nearer to the epicenter of fire) in the forest and transmits all sensed data to the base station through wireless communication as early as possible. Fire office takes necessary action to prevent the spreading of fire. For this purpose sensors are deployed in forest zone to sense different data which are necessary for detecting forest fire and divides it into different clusters. A semisupervised rule-based classification model is proposed in this paper to detect whether its zone is high active, medium active (MA) or low active (LA) cluster in the forest. We train our proposed integrated model in such a way when only one parameter of sensed data is transmitted by the sensor nodes due to energy constraint to the initiator of that zone, initiator can be able to predict the state of (HA,MA,LA) zone with 96% accuracy. All the sensor nodes in HA cluster transmit their packet through cluster head to the base station continuously applying greedy forwarding technique. Authors consider energy saving strategy during cluster head selection and data transmission in HA zone. On the other hand, sensors in MA zone transmit packet periodically and LA zone avoids to transmit the sensed data. This way proposed technique transmits the sensed data from HA zone efficiently and quickly to forest office for forest fire prevention and saves the energy of all sensor nodes in the forest.

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Bahrepour, M., Meratnia, N., & Havinga, P. J. M. (2009). Sensor fusion-based event detection in wireless sensor networks. IEEE.

Buscema, M. (1998). Back propagation neural networks. Substance Use & Misuse,33(2), 233–270.CrossRef

Chauhan, D., & Jawahar, T. (2014). Data mining techniques for weather prediction: A review. International Journal on Recent and Innovation Trends in Computing and Communication,2(8), 2184–2189.

Cheraghlou, M. N., Khadem-Zadeh, A., & Haghparast, M. (2017). Increasing lifetime and fault tolerance capability in wireless sensor networks by providing a novel management framework. Wireless Personal Communications,92(2), 603–622.CrossRef

Eshaftri, M., et al. (2015). A new energy efficient cluster based protocol for wireless sensor networks. In Federated conference on computer science and information systems (FedCSIS). IEEE.

Fang, Q., Jie, G., & Leonidas, J. G. (2006). Locating and bypassing holes in sensor networks. Mobile Networks and Applications,11(2), 187–200.CrossRef

Handy, M. J., Haase, M, & Timmermann, D. (2002). Low energy adaptive clustering hierarchy with deterministic cluster-head selection. In 4th international workshop on mobile and wireless communications network. IEEE.

Jain, A. K. (2010). Data clustering: 50 years beyond K-means. Pattern Recognition Letters,31(8), 651–666.CrossRef

Jin, C., & Luo, F. (2007). Forest fire detection system based on ZigBee wireless sensor network. China Forestry Science and Technology,20(6), 77–79.

10.

Kansal, A., Singh, Y., Kumar, Y., & Mohindru, V. (2015). Detection of forest fires using machine learning technique: A perspective. IEEE.

11.

Kour, H., & Sharma, A. K. (2010). Hybrid energy efficient distributed protocol for heterogeneous wireless sensor network. International Journal of Computer Applications, pp. 1–5.

12.

Kumar, D. Aseri, T. C., & Patel, R. B. (2009). EEHC: Energy efficient heterogeneous clustered scheme for wireless sensor networks. Computer Communications pp. 662–667.

13.

Liu, W.-J., & Kai-Ten, F. (2007). Greedy anti-void routing protocol for wireless sensor networks. IEEE Communications Letters, 11(7).

14.

Mann, P. S., & Satvir, S. (2017). Energy-efficient hierarchical routing for wireless sensor networks: A swarm intelligence approach. Wireless Personal Communications,92(2), 785–805.CrossRef

15.

Mittal, A., Geetika, S., & Ruchi, A. (2016). Forest Fire detection through various machine learning techniques using mobile agent in WSN. IRJET.

16.

Oladimeji, M. O., Turkey, M., Ghavami, M., & Dudley, S. (2015). A new approach for event detection using k-means clustering and neural networks. IEEE.

17.

Pande, V., Elmannai, W., Elleithy, K. (2013). Optimized algorithm for fire detection over WSN using Micaz Motes. IEEE, May.

18.

Provost, J. (1999). Naıve-bayes versus rule-learning in classification of email. University of Texas at Austin.

19.

Purkait, R., & Sachin, T. (2017). Energy aware fuzzy based multi-hop routing protocol using unequal clustering. Wireless Personal Communications,94(3), 809–833.CrossRef

20.

Qin, B., Yuni X., & Fang, L. (2009). DTU: a decision tree for uncertain data. Advances in Knowledge Discovery and Data Mining, pp. 4–15.

21.

Saleh, I., Eltoweissy, M., Ahbariya, A., & El-Sayed, H. (2007). A fault tolerance management. Framework for wireless sensor networks. Journal of Communications,2(4), 38–48.

22.

Singh, Y., Saha, S., Chugh, U., & Gupta, C. (2013). Distributed event detection in wireless sensor networks for forest fires. In 15th international conference on computer modelling and simulation. IEEE.

23.

Sokolova, M., & Guy, L. (2009). A systematic analysis of performance measures for classification tasks. Information Processing & Management,45(4), 427–437.CrossRef

24.

Trivedi, K., Srivastava, A. K. (2014). An energy efficient framework for detection and monitoring of forest fire using mobile agent in wireless sensor networks. IEEE.

25.

Tyagi, P., Gupta, R. P., & Gill, R. K. (2011). Comparative analysis of cluster based routing protocols used in heterogeneous wireless sensor network. International Journal of Soft Computing and Engineering (IJSCE), pp. 35–39.

26.

Yaakob, N., Khalil, I., Kumarage, H., Atiquzzaman, M., & Tari, Z. (2015). By-passing infected areas in wireless sensor networks using BPR. IEEE Transactions on Computers,64(6), 1594–1606.MathSciNetMATH

27.

Yadav, S. G. S. P., & Chaitra, A. (2012). Wireless sensor networks-architectures, protocols, simulators and applications: A survey. International Journal of Electronics and Computer Science Engineering (IJECSE), ISSN: 2277-1956, pp. 1941–1953.

28.

Yingwei, L., Narashiman, S., & Paramasivan, S. (1998). Performance evaluation of a sequential minimal radial basis function (RBF) neural network learning algorithm. IEEE Transactions on Neural Networks,9(2), 308–318.CrossRef

29.

Zhang, Y., Meratnia, N., & Havinga, P. (2010). Outlier detection techniques for wireless sensor networks: A survey. IEEE Communications Surveys & Tutorials,12(2), 159–170.CrossRef

Title: Semisupervised Classification Based Clustering Approach in WSN for Forest Fire Detection
Authors: Ditipriya Sinha
Rina Kumari
Sudhakar Tripathi
Publication date: 23-08-2019
Publisher: Springer US
Published in: Wireless Personal Communications / Issue 4/2019
Print ISSN: 0929-6212
Electronic ISSN: 1572-834X
DOI: https://doi.org/10.1007/s11277-019-06697-0

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