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Wireless Personal Communications

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08.08.2020

Live Emergency and Warning Alerts Through Android Application for Vehicular Ad Hoc Network Communication (Android VANET)

verfasst von: M. Milton Joe, B. Ramakrishnan

Erschienen in: Wireless Personal Communications | Ausgabe 1/2021

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Abstract

The technology is growing towards smart communication through smart devices. This smart communication leads to the development of Vehicular Ad Hoc Network (VANET). These days each vehicle is acting as a smart device which could establish a smart communication among the vehicles. The growth of VANET communication passes through various stages such as RoadSide Unit (RSU), Vehicle to Vehicle (V2V), Cluster based, Internet of Vehicles (IoV), and Web VANET (WVANET) Communication models. All these advancements in VANET architecture provide a smart communication among the vehicles. The vital aim of VANET architecture is to provide an efficient and effective emergency and warning alerts to the vehicles so that the vehicle can take appropriate decisions without any delay to safeguard the safety of the passengers. However, it will be more reliable to the vehicles if the VANET architecture could provide a live emergency and warning alerts to the vehicles in well ahead of time. In order to provide live emergency and warning alerts the communication as well as the device should be smart. In this paper, we have developed a live emergency and warning alerts to the vehicles though android application. Each vehicle will have the android application installed on it, in which the entire live driving scenario is provided. Once, the live driving scenario is provided, the live emergency and warning alerts can be shown to the vehicles in well ahead of time. As live emergency alerts are shown to the vehicles, it will help the vehicles to take the right decision more effectively.

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Asaar, M. R., Salmasizadeh, M., Susilo, W., & Majidi, A. (2018). A secure and efficient authentication technique for vehicular ad-hoc networks. IEEE Transactions on Vehicular Technology, 67(6), 5409.CrossRef

Zeadally, S., Hun, R., Chen, Y.-S., Irwin, A., & Hassan, A. (2012). Vehicular ad hoc networks (VANETs): Status, results, and challenges. Telecommunication Systems, 50(4), 217–241.CrossRef

Ghosh, M., Varghese, A., Gupta, A., Kherani, A. A., & Muthaiah, S. N. (2010). Detecting misbehaviors in VANET with integrated root-cause analysis. Ad Hoc Networks, 8(7), 778–790.CrossRef

Mohammed, N. H., El-Moafy, H. N., Abdel-Mageid, S. M., & Marie, M. I. (2017). Mobility management scheme based on smart buffering for vehicular networks. International Journal of Computer Networks and Applications (IJCNA), 4(2), 35–46.

Abdel-Mageid, S. (2016). Self-correcting localization scheme for vehicle to vehicle communication. International Journal of Computer Networks and Applications (IJCNA), 3(5), 95–107. https://doi.org/10.22247/ijcna/2016/48829.CrossRef

Mageid, S. A. (2017). Connectivity based positioning system for underground vehicular ad hoc networks. International Journal of Computer Networks and Applications (IJCNA), 4(1), 1–14.CrossRef

Ahmad, F., Franqueira, V. N., & Adnane, A. (2018). TEAM: a trust evaluation and management framework in context-enabled vehicular ad-hoc networks. IEEE Access, 6, 28643–28660.CrossRef

He, X., Shi, W., & Luo, T. (2018). Transmission capacity analysis for vehicular ad hoc networks. IEEE Access, 6, 30333–30341.CrossRef

Hajlaoui, R., Guyennet, H., & Moulahi, T. (2016). A survey on heuristic-based routing methods in vehicular ad-hoc network: Technical challenges and future trends. IEEE Sensors Journal, 16(17), 6782–6792.CrossRef

10.

Khan, Z., Fan, P., & Fang, S. (2017). On the connectivity of vehicular ad hoc network under various mobility scenarios. IEEE Access, 5, 22559–22565.CrossRef

11.

Yao, Y., Zhang, K., & Zhou, X. (2017). A flexible multi-channel coordination MAC protocol for vehicular ad hoc networks. IEEE Communications Letters, 21(6), 1305–1308.CrossRef

12.

Kim, D., Velasco, Y., Wang, W., Uma, R. N., Hussain, R., & Lee, S. (2017). A new comprehensive RSU installation strategy for cost-efficient VANET deployment. IEEE Transactions on Vehicular Technology, 66(5), 4200–4211.

13.

Ali, G. M. N., Chong, P. H. J., Samantha, S. K., & Chan, E. (2016). Efficient data dissemination in cooperative multi-RSU vehicular ad hoc networks (VANETs). Journal of Systems and Software, 117, 508–527.CrossRef

14.

Zhang, L., & Orosz, G. (2018). Beyond-line-of-sight identification by using vehicle-to-vehicle communication. IEEE Transactions on Intelligent Transportation Systems, 19(6), 1962–1972.CrossRef

15.

Won, M., Park, T., & Son, S. H. (2017). Toward mitigating phantom jam using vehicle-to-vehicle communication. IEEE Transactions on Intelligent Transportation Systems, 18(5), 1313–1324.CrossRef

16.

Abuashour, A., & Kadoch, M. (2017). Performance improvement of cluster-based routing protocol in VANET. IEEE Access, 5, 15354–15371.CrossRef

17.

Qi, W., Song, Q., Wang, X., Guo, L., & Ning, Z. (2018). SDN-enabled social-aware clustering in 5G-VANET systems. IEEE Access, 6, 28213–28224.CrossRef

18.

Darwish, T. S., & Bakar, K. A. (2018). Fog based intelligent transportation big data analytics in the internet of vehicles environment: Motivations, architecture, challenges, and critical issues. IEEE Access, 6, 15679–15701.CrossRef

19.

Joe, M. M., & Ramakrishnan, B. (2015). WVANET: Modelling a novel web based communication architecture for vehicular network. Wireless Personal Communications, 85(4), 1987–2001.CrossRef

20.

Joe, M. M., & Ramakrishnan, B. (2016). Review of vehicular ad hoc network communication models including WVANET (Web VANET) model and WVANET future research directions. Wireless Networks, 22(7), 2369–2386.CrossRef

21.

Joe, M. M., & Ramakrishnan, B. (2017). Novel authentication mechanism for checking node reliability in web vehicular ad hoc network. International Journal of Wireless and Mobile Computing, 13(2), 87–96.CrossRef

22.

Shivaldova, V., Paier, A., Smely, D., & Mecklenbra´uker, C. F. (2012). On roadside unit antenna measurements for vehicle to infrastructure communications. In: 23d IEEE International symposium on personal, indoor and mobile communications (PIMRC).

23.

Kumar, N., Chilamkurti, N., & Rodrigues, J. J. P. C. (2014). Learning automata-based opportunistic data aggregation and forwarding scheme for alert generation in vehicular ad hoc networks. Computer Communications, 39, 22–32.CrossRef

24.

Zhang, X. M., Zhang, Y., Yan, F., & Vasilakos, A. V. (2015). Interference-based topology control algorithm for delay-constrained mobile ad hoc networks. IEEE Transactions on Mobile Computing, 14(4), 742–754.CrossRef

25.

Yen, Y. S., Chao, H. C., Chang, R. S., & Vasilakos, A. (2011). Flooding-limited and multi-constrained QoS multicast routing based on the genetic algorithm for MANETs. Mathematical and Computer Modelling, 53(11–12), 2238–2250.CrossRef

26.

Zhou, L., Zhang, Y., Song, K., Jing, W., & Vasilakos, A. V. (2011). Distributed media services in P2P-based vehicular networks. IEEE Transactions on Vehicular Technology, 60(2), 692–703.CrossRef

27.

Ramakrishnan, B., Rajesh, R. S., & Shaji, R. S. (2010). An efficient vehicular communication outside the city environments. International Journal of Next-Generation Networks (IJNGN), 2(4), 1.CrossRef

28.

Ramakrishnan, B., Rajesh, R. S., & Shaji, R. S. (2011). CBVANET: A cluster based vehicular ad hoc network model for simple highway communication. International Journal of Advanced Networking and Applications, 2(4), 755–761.

29.

Viriyasitavat, W., Boban, M., Tsai, H.-M., & Vasilakos, A. V. (2015). Vehicular communications: Survey and challenges of channel and propagation models. IEEE Vehicular Technology Magazine, 10(2), 55–66.CrossRef

30.

Zeng, Y., Xiang, K., Li, D., & Vasilakos, A. V. (2013). Directional routing and scheduling for green vehicular delay tolerant networks. Wireless Networks, 19(2), 161–173.CrossRef

31.

Nishanth, R. B., Ramakrishnan, B., & Selvi, M. (2015). Improved signcryption algorithm for information security in networks. International Journal of Computer Networks and Applications (IJCNA), 2(3), 151–157.

32.

Ramakrishnan, B., Rajesh, R. S., & Namesh, C. (2010). A study on service procedure in clustered vehicular communication. International Journal of Advanced Research in Computer Science, 1(4), 535–542.

33.

Ramakrishnan, B. (2010). Analytical study of cluster and sans cluster vehicular adhoc network communication. International Journal of Computer Engineering and Information Technology, 25(1), 01–11.

34.

Lai, P. Y., Dow, C. R., & Chang, Y. Y. (2018). Rapid-response framework for defensive driving based on internet of vehicles using message-oriented middleware. IEEE Access, 6, 18548–18560.CrossRef

35.

Fangchun, Y., Shangguang, W., Jinglin, L., Zhihan, L., & Qibo, S. (2014). An overview of Internet of vehicles. China Communications, 11(10), 1–15.

36.

Aloqaily, M., Kantarci, B., & Mouftah, H. T. (2015) Vehicular clouds: State of the art, challenges and future directions. In: Proc. IEEE Jordan conf. appl. elect. eng. comput. technol. (AEECT), Nov. 2015, pp. 1–6

37.

Huang, J. M. (2013). Research on internet of vehicles and its application in intelligent transportation. In: Applied mechanics and materials (Vol. 321, pp. 2818–2821) Switzerland: Trans Tech Publications.

38.

Contreras, J., Zeadally, S., & Guerrero-Ibanez, J. A. (2017). Internet of vehicles: Architecture, protocols, and security. IEEE Internet of Things Journal, 99, 1–9.

39.

Sadiku, M. N., Tembely, M., & Musa, S. M. (2018). Internet of vehicles: An introduction. International Journals of Advanced Research in Computer Science and Software Engineering, 8(1), 11–13.CrossRef

40.

Ghazi, M. U., Khattak, M. A. K., Shabir, B., Malik, A. W., & Ramzan, M. S. (2020). Emergency message dissemination in vehicular networks: A review. IEEE Access, 8, 38606–38621.CrossRef

41.

Thakur T. T., Naik A., Vatari S., & Gogate M. (2016). Real time traffic management using Internet of Things. In: Proc. int. conf. commun. signal process. (ICCSP), Apr. 2016, pp. 1950–1953

42.

Balakrishna, S., & Thirumaran, M. (2018). Semantic interoperable traffic management framework for IoT smart city applications. EAI Endorsed Transactions on Internet of Things. https://doi.org/10.4108/eai.11-9-2018.CrossRef

Titel: Live Emergency and Warning Alerts Through Android Application for Vehicular Ad Hoc Network Communication (Android VANET)
verfasst von: M. Milton Joe
B. Ramakrishnan
Publikationsdatum: 08.08.2020
Verlag: Springer US
Erschienen in: Wireless Personal Communications / Ausgabe 1/2021
Print ISSN: 0929-6212
Elektronische ISSN: 1572-834X
DOI: https://doi.org/10.1007/s11277-020-07708-1

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