Authors: Ahmad Aljaafreh

Abstract:

Safer driver behavior promoting is the main goal of this paper. It is a fact that drivers behavior is relatively safer when being monitored. Thus, in this paper, we propose a monitoring system to report specific driving event as well as the potentially aggressive events for estimation of the driving performance. Our driving monitoring system is composed of two parts. The first part is the in-vehicle embedded system which is composed of a GPS receiver, a two-axis accelerometer, radar sensor, OBD interface, and GPRS modem. The design considerations that led to this architecture is described in this paper. The second part is a web server where an adaptive hierarchical fuzzy system is proposed to classify the driving performance based on the data that is sent by the in-vehicle embedded system and the data that is provided by the geographical information system (GIS). Our system is robust, inexpensive and small enough to fit inside a vehicle without distracting the driver.

Keywords: Driving monitoring system, In-vehicle embedded system, Hierarchical fuzzy system.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1060898

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References:

[1] D. Johnson and M. Trivedi, "Driving style recognition using a smartphone as a sensor platform," in Intelligent Transportation Systems (ITSC), 2011 14th International IEEE Conference on, oct. 2011, pp. 1609 -1615.
[2] W. J. Horrey, M. F. Lesch, M. J. Dainoff, M. M. Robertson, and Y. I. Noy, "On-board safety monitoring systems for driving: Review, knowledge gaps, and framework," Journal of Safety Research, vol. 43, no. 1, pp. 49 - 58, 2012. (Online). Available: http://www.sciencedirect.com/science/article/pii/S0022437511001575
[3] C. M. Farmer, B. B. Kirley, and A. T. McCartt, "Effects of in-vehicle monitoring on the driving behavior of teenagers," Journal of Safety Research, vol. 41, no. 1, pp. 39 - 45, 2010. (Online). Available: http://www.sciencedirect.com/science/article/pii/S0022437510000058
[4] Z. Zhu and Q. Ji, "Real time and non-intrusive driver fatigue monitoring," in Intelligent Transportation Systems, 2004. Proceedings. The 7th International IEEE Conference on, oct. 2004, pp. 657 - 662.
[5] J.-D. Lee, J.-D. Li, L.-C. Liu, and C.-M. Chen, "A novel driving pattern recognition and status monitoring system," in Advances in Image and Video Technology, ser. Lecture Notes in Computer Science, L.-W. Chang and W.-N. Lie, Eds. Springer Berlin / Heidelberg, vol. 4319, pp. 504- 512.
[6] D. Sandberg, T. Akerstedt, A. Anund, G. Kecklund, and M. Wahde, "Detecting driver sleepiness using optimized nonlinear combinations of sleepiness indicators," Intelligent Transportation Systems, IEEE Transactions on, vol. 12, no. 1, pp. 97 -108, march 2011.
[7] I. Mohamad, M. Ali, and M. Ismail, "Abnormal driving detection using real time global positioning system data," in Space Science and Communication (IconSpace), 2011 IEEE International Conference on, july 2011, pp. 1 -6.
[8] U. T. D. E. J. Krajewski, D. Sommer and M. Golz, "Steering wheel behavior based estimation of fatigue," in The 5th international driving symposium on human factors in driver assessment, Training and vehicle design, June 2009, pp. 118-124.
[9] J. Dai, J. Teng, X. Bai, Z. Shen, and D. Xuan, "Mobile phone based drunk driving detection," in Pervasive Computing Technologies for Healthcare (PervasiveHealth), 2010 4th International Conference on- NO PERMISSIONS, march 2010, pp. 1 -8.
[10] T. Imkamon, P. Saensom, P. Tangamchit, and P. Pongpaibool, "Detection of hazardous driving behavior using fuzzy logic," in Electrical Engineering/ Electronics, Computer, Telecommunications and Information Technology, 2008. ECTI-CON 2008. 5th International Conference on, vol. 2, may 2008, pp. 657 -660.
[11] W. Hailin, L. Hanhui, and S. Zhumei, "Fatigue driving detection system design based on driving behavior," in Optoelectronics and Image Processing (ICOIP), 2010 International Conference on, vol. 1, nov. 2010, pp. 549 -552.
[12] R. Zantout, M. Jrab, L. Hamandi, and F. Sibai, "Fleet management automation using the global positioning system," in Innovations in Information Technology, 2009. IIT -09. International Conference on, 2009, pp. 30 -34.
[13] S. Thong, C. T. Han, and T. Rahman, "Intelligent fleet management system with concurrent gps gsm real-time positioning technology," in Telecommunications, 2007. ITST -07. 7th International Conference on ITS, 2007, pp. 1 -6.
[14] J. Lin, S.-C. Chen, Y.-T. Shih, and S.-H. Chen, "A study on remote online diagnostic system for vehicles by integrating the technology of obd, gps, and 3g," World Academy of Science, Engineering and Technology 56 2009, vol. 56, pp. 435-441, 2009.
[15] S. Kim, K. Wilson-Remmer, A. Kun, and I. Miller, W.T., "Remote fleet management for police cruisers," in Intelligent Vehicles Symposium, 2005. Proceedings. IEEE, 2005, pp. 30 - 35.
[16] C.-M. Chou, C.-Y. Li, W.-M. Chien, and K. chan Lan, "A feasibility study on vehicle-to-infrastructure communication: Wifi vs. wimax," in Mobile Data Management: Systems, Services and Middleware, 2009. MDM -09. Tenth International Conference on, May 2009, pp. 397 - 398.
[17] D. Stojanovic, B. Predic, I. Antolovic, and S. Dordevic-Kajan, "Web information system for transport telematics and fleet management," in Telecommunication in Modern Satellite, Cable, and Broadcasting Services, 2009. TELSIKS -09. 9th International Conference on, 2009, pp. 314 -317.
[18] J. Wang, W. Xu, and Y. Gong, "Real-time driving dangerlevel prediction," Engineering Applications of Artificial Intelligence, vol. 23, no. 8, pp. 1247 - 1254, 2010. (Online). Available: http://www.sciencedirect.com/science/article/pii/S0952197610000175