Abstract
The goal of V2V Vehicle-to-Vehicle communication is to prevent accidents by allowing vehicles in transit to send position and speed data to one another over an ad hoc mesh network. Depending upon how the technology is implemented, the vehicle’s driver may simply receive a warning should there be a risk of an accident or the vehicle itself may take pre-emptive actions such as braking to slow down. V2V technology represents the next great advance in saving lives. This technology could move us from helping people survive crashes to helping them avoid crashes altogether—saving lives, saving money, and even saving fuel thanks to the widespread benefits it offers
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
Similar content being viewed by others
References
Islim, M.S., Haas, H.: Modulation Techniques for Li-Fi. ISSN. 1673-5188, 4 February 2016
U.S. Transportation Secretary Anthony Foxx. http://www.nhtsa.gov/About+NHTSA/Press+Releases/NHTSA-issues-advanced-notice-of-proposed-rulemaking-on-V2V-communications
Uysal, M., Ghassemlooy, Z., Bekkali, A., Kadri, A., Menouar, H.: Performance study of a V2V system using a measured headlamp beam pattern model. https://doi.org/10.1109/mvt.2015.2481561
Tsonev, D., Videv, S., Haas, H.: Light Fidelity (Li-Fi): Towards All-Optical Networking
Morgan, Y.L.: Notes on DSRC & WAVE standards suite: its architecture, design, and characteristics. IEEE Commun. Surveys Tut. 12(4), 504–518 (2010)
Lee, S.J., Kwon, J.K., Jung, S.Y., Kwon, Y.H.: Simulation modeling of visible light communication channel for automotive applications. In: Proceedings of 15th International IEEE Conference Intelligent Transportation Systems, pp. 463–468 (2012)
Mesleh, R., Elgala, H., Haas, H.: On the performance of different OFDM based optical wireless communication systems. J. Opt. Commun. Netw. 3(8), 620–628 (2011)
Kizilirmak, R.C., Uysal, M.: Relay-assisted OFDM transmission for indoor visible light communication. In: Proceedings IEEE International Black Sea Conference Communications Networking, pp. 11–15 (2014)
Akanegawa, M., Tanaka, Y., Nakagawa, M.: Basic study on traffic information system using LED traffic lights. IEEE Trans. Intell. Transport. Syst. 2(4), 197–203 (2001)
Kitano, S., Haruyama, S., Nakagawa, M.: LED road illumination communications system. In: Proceedings IEEE 58th Vehicular Technology Conference Fall, vol. 5, pp. 3346–3350 (2003)
Liu, C., Sadeghi, B., Knightly, E.: Enabling vehicular visible light communication (V2LC) networks. In: Proceedings of 8th ACM International Workshop Vehicular Inter-Networking, pp. 41–50 (2011)
Lourenco, N., Terra, D., Kumar, N., Alves, L.N., Aguiar, R.L.: Visible light communication system for outdoor applications. In: Proceedings of 8th International Symposium Communication Systems, Networks Digital Signal Processing, pp. 1–6 (2012)
Yu, S.-H., Shih, O., Tsai, H.-M., Wisitpongphan, N., Roberts, R.: Smart automotive lighting for vehicle safety. IEEE Commun. Mag. 51(12), 50–59 (2013)
Takai, I., Harada, T., Andoh, M., Yasutomi, K., Kagawa, K., Kawahito, S.: Optical vehicle-to-vehicle communication system using LED transmitter and camera receiver. IEEE Photon. J. 6(5), 1–14 (2014)
Tomas, B., Tsai, H.-M., Boban, M.: Simulating vehicular visible light communication: physical radio and MAC modeling. In: Proceedings of IEEE Vehicular Networking Conference, pp. 222–225 (2014)
Luo, P., Ghassemlooy, Z., Minh, H.L., Tang, X., Tsai, H.-M.: Undersampled phase shift ON-OFF keying for camera communication. In: Proceedings of 6th International Conference Wireless Communications Signal Processing, pp. 1–6 (2014)
Martinez, F.J., et al.: Emergency services in future intelligent transportation systems based on vehicular communication networks. IEEE Intell. Transp. Syst. Mag. 2(2), 6–20 (2010)
Meroth, A.M., et al.: Functional safety and development process capability for intelligent transportation systems. IEEE Intell. Transp. Syst. Mag. 7(4), 12–23 (2015)
Karagiannis, O., et al.: Vehicular networking: a survey and tutorial on requirements, architectures, challenges, standards and solutions. IEEE Commun. Surveys Tut. 13(4), 584–616 (2011)
Zheng, K., et al.: Heterogeneous vehicular networking: a survey on architecture, challenges, and solutions. IEEE Commun. Surveys Tut. 17(4), 2377–2396 (2015)
Intelligent transport systems (ITS) usage in ITU Member States: Working Document toward a Preliminary Draft New Report ITU-R M. [ITS USAGE], Annex 32 to Document 5A/469-E, June 2017
Uysal, M., Ghassemlooy, Z., Bekkali, A., Kadri, A., Menouar, H.: Visible light communication for vehicular networking: performance study of a V2V system using a measured headlamp beam pattern model. IEEE Veh. Technol. Mag. 10(4), 45–53 (2015)
Karunatilaka, D., Zafar, F., Kalavally, V., Parthiban, R.: LED based indoor visible light communications: state of the art. IEEE Commun. Surveys Tutor. 17(3), 1649–1678 (2015)
Pathak, P.H., Feng, X., Hu, P., Mohapatra, P.: Visible light communication, net-working, and sensing: a survey, potential and challenges. IEEE Commun. Surveys Tutor. 17(4), 2047–2077 (2015)
Yu, S.H., et al.: Smart automotive lighting for vehicle safety. IEEE Commun. Mag. 51(12), 50–59 (2013)
Cailean, A.M., Dimian, M.: Current challenges for visible light communications usage in vehicle applications: a survey. IEEE Commun. Surveys Tutor. 19(4), 2681–2703 (2017)
Cailean, A.M., Dimian, M.: Impact of IEEE 802.15. 7 standard onvisible light communications usage in automotive applications. IEEE Commun. Mag. (2017). https://doi.org/10.1109/mcom.2017.1600206cm
Akanegawa, M., Tanaka, Y., Nakagawa, M.: Basic study on traffic information system using LED traffic lights. IEEE Trans. Intell. Transp. Syst. 2(4), 197–203 (2001)
Kumar, N., Terra, D., Lourenco, N., Alves, L.N., Aguiar, R.L.: Visible light communication for intelligent transportation in road safety applications. In: Proceedings of IEEE International Conference Wireless Communications and Mobile Computing, pp. 1513–1518 (2011)
Viriyasitavat, W., et al.: Short paper: channel model for visible light communications using off-the-shelf scooter taillight. In: IEEE Vehicular Networking Conference (VNC), pp. 170–173 (2013)
Lee, S.J., Kwon, J.K., Jung, S.Y., Kwon, Y.H.: Evaluation of visible light communication channel delay profiles for automotive applications. EURASIP J. Wirel. Commun. Netw. 2012(370), 1–8 (2012)
Luo, P., et al.: Fundamental analysis of a car to car visible light communication system. In: 9th International Symposium Communication Systems, Networks & Digital Signal Processing (CSNDSP), pp. 1011–1016 (2014)
Luo, P., et al.: Performance analysis of a car-to-car visible light communication system. Appl. Opt. 54(7), 1696–1706 (2015)
Kim, Y.H., Cahyadi, W.A., Chung, Y.H.: Experimental demonstration of LED-based vehicle to vehicle communication under atmospheric turbulence. In: IEEE International Conference Information and Communication Technology Convergence (ICTC), pp. 1143–1145 (2015)
Kim, Y.H., Cahyadi, W.A., Chung, Y.H.: Experimental demonstration of VLC-based vehicle-to-vehicle communications under fog conditions. IEEE Photon. J. 7(6), 1–9 (2015)
Schulz, D., Jungnickel, V., Das, S., Hohmann, J., Hilt, J., Hellwig, P., Paraskevopoulos, A., Freund, R.: Long-term outdoor measurements using a rate-adaptive hybrid optical wireless/60 GHz link over 100 m. In: IEEE 19th International Conference Transparent Optical Networks (ICTON), pp. 1–4 (2017)
Uysal, M., Capsoni, C., Ghassemlooy, Z., Boucouvalas, A., Udvary, E.: Optical Wireless Communications: An Emerging Technology. Springer (2016)
Stark, R.E.: Road surfaces reflectance influences lighting design. Light. Design Appl. (1986)
Agreement Addendum 111: Regulation No. 112 Revision 3-unece (2013)
Miramirkhani, F., Narmanlioglu, O., Uysal, M., Panayirci, E.: A mobile channel model for VLC and application to adaptive system design. IEEE Commun. Lett. 21(5), 1035–1038 (2017)
Goldsmith, A.: Wireless Communications. Cambridge University Press, Cambridge (2004)
Fath, T., Haas, H.: Performance comparison of MIMO techniques for optical wireless communications in indoor environment. IEEE Trans. Commun. 61(2), 733–742 (2013)
Morgado, E., Mora-Jimenez, I., Vinagre, J.J., Ramos, J., Caamano, A.J.: End-to-end average BER in multihop wireless networks over fading channels. IEEE Trans. Wirel. Commun. 9(8), 2478–2487 (2010)
Florea, A., Yanikomeroglu, H.: On the optimal number of hops in infrastructure-based fixed relay networks. In: IEEE Global Telecommunications Conference (GLOBECOM 2005), pp. 3242–3247 (2005)
Sperling, L.H.: Introduction to Physical Polymer Science. Wiley, New York (2005)
Grubor, J., Randel, S., Langer, K.D., Walewski, J.W.: Broadband information broadcasting using LED-based interior lighting. J. Lightwave Technol. 26(24), 3883–3892 (2008)
Ucar, S., Ergen, S., Ozkasap, O.: IEEE 802.11p and visible light hybrid communication based secure autonomous platoon. IEEE Trans. Veh. Technol. 67(9), 8667–8681 (2018)
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2021 Springer Nature Switzerland AG
About this paper
Cite this paper
Ivascu, CO., Ursutiu, D., Samoila, C. (2021). Visible Light Communication for Automotive Market Weather Conditions Simulation. In: Auer, M., May, D. (eds) Cross Reality and Data Science in Engineering. REV 2020. Advances in Intelligent Systems and Computing, vol 1231. Springer, Cham. https://doi.org/10.1007/978-3-030-52575-0_53
Download citation
DOI: https://doi.org/10.1007/978-3-030-52575-0_53
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-030-52574-3
Online ISBN: 978-3-030-52575-0
eBook Packages: Intelligent Technologies and RoboticsIntelligent Technologies and Robotics (R0)