VLC-Based Car-to-Car Communication
DOI:
https://doi.org/10.14203/jet.v20.16-22Keywords:
Car-to-Car Communication, ECU, Visible Light Communication, Infrared CommunicationAbstract
Based on data from the Indonesian Traffic Corps by September 2019, the number of car accidents was dominated by rear-hit crashes with 6,966 accidents. Most of these accidents occurred during car convoys. It needs a car-to-car communication to increase driver awareness. One of the technologies that can be applied is Visible Light Communication (VLC) and infrared communication. The transmitted data are the vehicle speed data, throttle position, and brake stepping indicator. The data are obtained by reading the Engine Control Unit (ECU) in the car. The data are packaged from the three data and sent to other cars at day and night using VLC and infrared communication. The experimental results show that in a communication system that uses VLC, data can be exchanged between cars during the day up to 2 meters and at night up to 11 meters. Otherwise, in infrared communication, vehicles can communicate during the day up to 2 meters and at night up to 0.7 meter. The test was also carried out with some conditions such as rain, smoke, passers, and other vehicle lights.
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References
Polri. (2018, September 10). Accidents in Indonesia During the Last Quarter [Online]. Available: http://korlantas.polri.go.id/artikel/korlantas/113?Statistik_Laka#tab_1.
Polri. (2018, September 10). Type of Accident [Online]. Available: http://korlantas.polri.go.id/artikel/korlantas/113?Statistik_Laka#tab_2.
J. M. Sullivan and M. J. Flannagan, “Risk of fatal rear-end collisions: is there more to it than attention?” in Proc. Driving Assessment 2003: Second Int. Driving Symp. Human Factors Driver Assessment, Training Vehicle Design, Park City, Utah, 2003, pp. 239-244. Crossref
R. S. Raw, S. Das, “Performance comparison of position-based routing protocols in vehicle-to-vehicle (V2V) communication,” Int. J. Eng. Sci. Technol., vol. 3, no. 1, pp. 435-444, 2011.
I. Takai, T. Harada, M. Andoh, K. Yasutomi, K. Kagawa, and S. Kawahito, “Optical vehicle-to-vehicle communication system using LED transmitter and camera receiver,” IEEE Photonics J., vol. 6, no. 5, pp. 1-14, Oct. 2014. Crossref
R. A. Khan, A. Gogoi, R. Srivastava, S. K. Tripathy, S. Manikandaswamy, “Automobile collision warning and identification system using visible light and Wi-Fi communication,” Int. J. Eng. Adv. Technol., vol. 8, no. 583, pp. 72-77, 2019. Crossref
Y. H. Kim, W. A. Cahyadi, and Y. H. Chung, “Experimental demonstration of VLC-based vehicle-to-vehicle communications under fog conditions,” IEEE Photonics J., vol. 7, no. 6, pp. 1-9, Dec. 2015. Crossref
W. Shen and H. Tsai, “Testing vehicle-to-vehicle visible light communications in real-world driving scenarios,” in Proc. 2017 IEEE Veh. Netw. Conf., Torino, 2017, pp. 187-194. Crossref
M. Y. Abualhoul, O. Shagdar, and F. Nashashibi, “Visible light inter-vehicle communication for platooning of autonomous vehicles,” in Proc. 2016 IEEE Intell. Vehicles Symp., Gothenburg, 2016, pp. 508-513. Crossref
S. Kulkarni, A. Darekar and S. Shirol, “Proposed framework for V2V communication using Li-Fi technology,” in Proc. 2017 Int. Conf. Circuits Controls Commun., Bangalore, 2017, pp. 187-190. Crossref
Y. P. Kusumo, Harianto, and M. C. Wibowo, “Rancang bangun sistem general diagnostic scanner untuk mengakses ECU mobil dengan komunikasi serial OBD-2,” J. Control Netw. Syst., vol. 4, no. 1, pp. 69-82, 2015.
M. E. Echsony and K. Nurfaizin, “Monitoring engine control unit (ECU) pada mesin toyota avanza 1300 cc menggunakan personal computer,” J. Elect. Electron. Control Autom. Eng., vol. 3, no. 2, pp. 183-188, 2018. Crossref
M. I. Abdillah, R. A. P and D. Darlis, “Distance measurement implementation for VLC-based V2V communication on motorbike platooning,” presented at Int. Conf. Eng. Technol. Entrepreneurship 2019, Bandung, 2019.
D. Y. Daniel, R. A. Priramadhi and D. Darlis, “ECU logger: Perancangan sistem penyimpanan dan monitoring data elektronik mobil,” e-Proc. Eng., vol. 6, no. 2, pp. 2699-2706, 2019.
H. Januar, D. Darlis and A. Hartaman, “Realisasi prototype smartcar menggunakan sistem visible light communication,” e-Proc. Appl. Sci., vol. 5, no. 3, pp. 3118-3131, 2019.
I. P. Wulandari, “Pembuatan alat ukur kecepatan respon manusia berbasis mikrokontroller AT89S8252,” J. Neutrino, vol. 1, no. 2, pp. 208-219, 2009.
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