[1] Alliance, Z. (2006). ZigBee specification. Document

053474r06. Retrieved from Document 053474r06, Version 1

(2006).

[2] Bagheri, M. (2007). Efficient K-Coverage

Algorithms for Wireless Sensor Networks and Their

Applications to Early Detection of Forest Fires. Computing

Science SIMON FRASER UNIVERSITY, MSc:75.

[3] Bahrepour, M., Nirvana, M., & Havinga, P. J. (2008).

Automatic fire detection: A survey from wireless sensor

network perspective.

[4] Breejen, & E., M. B. (1998). Autonomous forest

fire detection. Third International Conference on Forest Fire

Research and Fourteenth Conference.

[5] Burgan, R. E. (1988). National Fire-Danger Rating

System. Asheville, NC: U.S. Department of Agriculture,

Forest Service, Southeastern Forest Experiment, Res. Pap.

SE-273.

[6] Cano, A., Reig, C., Milan-Scheiding, C., & Lopez_xfffe_Baeza. (2012). Automated Soil Moisture Monitoring

Wireless Sensor Network for Long-Term CalVal

Applications. Wireless Sensor Network, 4 (8).

[7] Chae, M., Yoo, H., Kim, J., & Cho, M. (2006).

Bridge Condition Monitoring System Using Wireless

Network (CDMA and Zigbee). 23rd International

Symposium on Automation and Robotics in Construction

ISARC 2006, Tokyo, Japan, 3 – 5 Oct.

[8] Chen, Z. (2013). A review of automated formal

verification of ad hoc routing protocols for wireless sensor

networks. arXiv preprint arXiv, 305.7410.

[9] Chowdhury, N., Mahabub, H., & Samiul, I. (2013).

IOT: Detection of Keys, Controlling Machines, and Wireless

Sensing Via Mesh Networking through Internet. Global

Journal of Researches In Engineering.

[10] Cracknell, A. P. (1997). The Advanced Very High_xfffe_Resolution Radiometer (AVHRR). CRC Press.

[11] Dutta, D., Dilip, K., & Arindam, K. (2013).

Analysis of IEEE 802.15. 4 MAC under low duty cycle.

arXiv preprint arXiv:1301.6532. edition.cnn. (2013, 20 12).

http://edition.cnn.com/2013/10/20/world/asia/australia-fires/.

Retrieved from http://edition.cnn.com: http://edition.cnn.

com/2013/10/20/world/asia/australia-fires/.

[12] Flannigan, M. D. (1998). Future wildfire in

circumboreal forests in relation to global warming. Journal

of Vegetation Science, 469-476.

[13] Fleming, G., & Robertson, R. (October 2003.).

Fire Management Tech Tips: The Osborne Fire Finder. USA:

Technical Report 0351 1311-SDTDC, USDA Forest Service.

[14] Forestry Division Newsdesk, N. (2008). http://

www.dfr.state.nc.us/news_pubs/. Retrieved 01 12, 2013,

from http://www.dfr.state.nc.us/news_pubs/: http://www.dfr.

state.nc.us/news_pubs/.

[15] García, H., & Ana, B. (2008). WSN Application

Scenarios.London: Springer.

[16] Gat, E. (1998, Retrieved 2008-04-06). On three_xfffe_layer architectures. Artificial Intelligence and Mobile

Robots, 195–210.

[17] Groot., W. J. (1998). Interpreting the Canadian

Forest Fire Weather Index (FWI) System. In Proc. of the

Fourth Central Region Fire Weather Committee Scientific

and Technical Seminar, Edmonton, Canada.

[18] Gungor, V. C., & Gerhard, P. (2013). Industrial

Wireless Sensor Networks: Applications, Protocols, and

Standards.CRC Press.

[19] Hussain, A., & Niazi, M. (2010). A novel agent_xfffe_based simulation framework for sensing in complex adaptive

environments. IEEE Sensors Journal, 11 (0), doi:10.1109/

JSEN.2010.2068044.

[20] J. San-Miguel-Ayanz, J. C. (2003). Section 2:

Current methods to assess fire danger potential. In Wildland

Fire Danger Estimation and Mapping The Role of Remote

Sensing Data. World Scientific Publishing Co. Pte Ltd.

[21] Karali, A. (2013). Evaluation of the Canadian Fire

Weather Index in Greece and Future Climate Projections.

Advances in Meteorology, Climatology and Atmospheric

Physics. Springer Berlin Heidelberg, 501-508.

[22] Knuth, D. E. (1977). A generalization of Dijkstra’s

algorithm. In Information Processing Letters 6.1 (pp. 1-5).

[23] Lee, & Tsung-Han. (2013). Modeling and

Performance Analysis of Route-Over and Mesh-Under

Routing Schemes in 6LoWPAN under Error-Prone Channel

Condition. Journal of Applied Mathematics 2013.

[24] Lee, S.-J., Gerla, M., & Toh, C.-K. (1999). A

simulation study of table-driven and on-demand routing

protocols for mobile ad hoc networks. Network, IEEE, 13

(4), 48-54.

[25] Lim, Y.-s., & S. Lim, e. a. (2007). A Fire Detection

and Rescue Support Framework with Wireless Sensor

Networks. Convergence Information Technology.

[26] Milke, J. A., & McAvoy, T. J. (1995). Analysis of

signature patterns for discriminating.

[27] Muller, H. C., & Fischer, A. (1995). A robust

fire detection algorithm for temperature and optical smoke

density using fuzzy logic. Security Technology, Sanderstead.

[28] Niazi, M., & Hussain, A. (2009). Agent-based

tools for modeling and simulation of self-organization in

peer-to-peer, ad-hoc and other complex networks. IEEE

Communications Magazine, 47 (3), 163 - 173.

[29] Okayama, Y. (1991). A primitive study of a fire

detection method controlled by the artificial neural net. Fire

Safety Journal, 17 (6), 535-553.

[30] PAK, M. (2012, 06 06). http://www.microsoft.com/

enpk/default.aspx. Retrieved from http://www.microsoft.

com.

[31] Pripužic, K. H. (2008). Early Forest Fire Detection

with Sensor Networks: Sliding Windows Skylines Approach.

Faculty of Electrical Engineering and Computing,

Department of Telecommunication, White Paper.

[32] Silberschatz, A., Galvin, P. B., & Gagne, G. (2010).

Process Scheduling. (J. (Asia), Ed.) Operating System

Concepts (8th ed.).

[33] Son, B., Yong-sork, H., & J, K. (2008). A design

and implementation of a forest-fires surveillance system

based on wireless sensor networks for South Korea

mountains. International Journal of Computer Science and

Network Security (IJCSNS), 12 (6.9), 124-130.

[34] Thuillard, M. (2000). Application of Fuzzy

Wavelets and Wavelets in Soft Computing.

[35] Tiwari, A., Ballal, P., & Frank, L. (2007). Lewis

Energyefficient wireless sensor network design and

implementation for condition-based maintenance. ACM

Transactions on Sensor Networks (TOSN) archive, Volume

3, Issue 1.

[36] Tymstra, C., Bryce, R., & Wotton, B. (2009).

Development and structure of Prometheus: the Canadian

wildland fire growth simulation model. Nat. Resour. Can.,

can. For. Serv., North. For. Cent., Edmonton, AB. Inf. Rep.

NOR-X-417.

[37] Vescoukis, V., & T. Olma, e. a. (2007). Experience

from a Pilot Implementation of an “InSitu Forest

Temperature Measurement Network. Personal, Indoor and

Mobile Radio Communications”.

[38] Viani, F., Rocca, P., Oliveri, G., & Massa, A.

(2012). Pervasive remote sensing through WSNs. Antennas

and Propagation (EUCAP), 2012 6th European Conference

on, (pp. 49-50).

[39] Yu, L., & Wang. (2005). Real-time forest fire

detection with a wireless sensor.

[40] Zhiping, L., & Q. Huibin, e. a. (2006). The Design

of Wireless Sensor Networks for Forest Fire Monitoring

System. School of Electronics and Information, Hangzhou

Dianzi University.

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