Through facilitating connectivity between automobiles and their surroundings, vehicular ad hoc networks, or VANETs, significantly contribute to improvements in road safety, traffic efficiency, and passenger comfort. Nevertheless, because networks are both open and changing, roadside devices collect vital safety information. By bolstering general security with the use of wireless communication networks (WSNs), this study helps bring about a safe transportation system. The proposed system employs a distributed network of mobile sensors embedded inside the VANET framework to track and detect roadside surroundings. Together, these sensors gather and process information about the movements of vehicles and traffic patterns. The authority, secrecy, integrity, availability of multifunctional safety applications have been implemented through use of V2V (vehicle to vehicle) connectivity and collected data. NS 2.35 platform is used to validate simulated analysis, and it is shown that suggested analysis works well with various transport intelligence systems in ad hoc networks (VANETs). In light of this, deployment demonstrates data confidentiality, integrity, overall network resilience, opening the door to more secure and safe communication. The performance evaluation metrics are quality of service (QoS) for forward collision warning (FCW) and lane change warning (LCW), communication delay (CD) and packet loss rate (PLR) used for this experiment.

1. Okpok M, Kihei B. Challenges and Opportunities for Multimedia Transmission in Vehicular Ad Hoc Networks: A Comprehensive Review. Electronics. 2023; 12(20): 4310. doi: 10.3390/electronics12204310

2. Khanpara P, Bhojak S. Routing Protocols and Security Issues in Vehicular Ad hoc Networks: A Review. Journal of Physics: Conference Series. 2022; 2325(1): 012042. doi: 10.1088/1742-6596/2325/1/012042

3. Choudhary D, Pahuja R. Awareness routing algorithm in vehicular ad-hoc networks (VANETs). Journal of Big Data. 2023; 10(1). doi: 10.1186/s40537-023-00742-3

4. Oladimeji D, Gupta K, Kose NA, et al. Smart Transportation: An Overview of Technologies and Applications. Sensors. 2023; 23(8): 3880. doi: 10.3390/s23083880

5. Ali ZH, Ali HA. Energy-efficient routing protocol on public roads using real-time traffic information. Telecommunication Systems. 2023; 82(4): 465-486. doi: 10.1007/s11235-023-00993-8

6. Toulni H, Miyara M, Filali Y, et al. Preventing urban traffic congestion using VANET technology in urban area. Koumétio Tékouabou SC, Chenal J, Diop EB, Azmi R, eds. E3S Web of Conferences. 2023; 418: 02005. doi: 10.1051/e3sconf/202341802005

7. Emara K, Woerndl W, Schlichter J. Vehicle tracking using vehicular network beacons. In: Proceedings of the 2013 IEEE 14th International Symposium on “A World of Wireless, Mobile and Multimedia Networks” (WoWMoM). doi: 10.1109/wowmom.2013.6583473

8. Wiedersheim B, Ma Z, Kargl F, et al. Privacy in inter-vehicular networks: Why simple pseudonym change is not enough. In: Proceedings of the 2010 Seventh International Conference on Wireless On-demand Network Systems and Services (WONS). doi: 10.1109/wons.2010.5437115

9. Sampigethaya K, Li M, Huang L, Poovendran R. AMOEBA: Robust location privacy scheme for VANET. IEEE Journal on Selected Areas in communications. 2007; 25(8): 1569-1589.

10. Freudiger J, Raya M, Felegyh M, et al. Mix-Zones for Location Privacy in Vehicular Networks. In: ACM Workshop on Wireless Networking for Intelligent Transportation Systems (WiN-ITS); Vancouver, Canada; 2007. pp. 1-7.

11. Buttyán L, Holczer T, Weimerskirch A, Whyte W. Slow: A practical pseudonym changing scheme for location privacy in vanets. In: Proceedings of the 2009 IEEE vehicular networking conference (VNC); 28–30 October 2009; Tokyo, Japan. pp. 1-8.

12. Wei YC, Chen YM. Safe distance based location privacy in vehicular networks. In: Proceedings of the 2010 IEEE 71st Vehicular Technology Conference; 16–19 May 2010; Taipei, Taiwan. pp. 1-5.

13. Palanisamy B, Liu L. Attack-Resilient Mix-zones over Road Networks: Architecture and Algorithms. IEEE Transactions on Mobile Computing. 2015; 14(3): 495-508. doi: 10.1109/tmc.2014.2321747

14. Yu R, Kang J, Huang X, et al. MixGroup: Accumulative Pseudonym Exchanging for Location Privacy Enhancement in Vehicular Social Networks. IEEE Transactions on Dependable and Secure Computing. 2016; 13(1): 93-105. doi: 10.1109/tdsc.2015.2399291

15. Schoch E, Kargl F, Leinmüller T, et al. Impact of pseudonym changes on geographic routing in vanets. In: Proceedings of the Security and Privacy in Ad-Hoc and Sensor Networks: Third European Workshop, ESAS; 20–21 September 2006; Hamburg, Germany. pp. 43-57.

16. Calandriello G, Papadimitratos P, Hubaux, JP, Lioy A. Efficient and robust pseudonymous authentication in VANET. In: Proceedings of the fourth ACM international workshop on Vehicular ad hoc networks; 2007. pp. 19-28.

17. Hoh B, Gruteser M. Protecting location privacy through path confusion. In: Proceedings of the First International Conference on Security and Privacy for Emerging Areas in Communications Networks (SECURECOMM’05); 5–9 September 2005; Athens, Greece. pp. 194-205.

18. Lefevre S, Petit J, Bajcsy R, Laugier C, Kargl F. Impact of v2x privacy strategies on intersection collision avoidance systems. In: Proceedings of the IEEE Vehicular Networking Conference; 16–18 December 2013; Boston, MA, USA. pp. 71-78.

19. Yang T, Zhang Y, Tan J. Research on forward collision warning system based on connected vehicle V2V communication. In: Proceedings of the 5th International Conference on Transportation Information and Safety (ICTIS). pp. 1174-1181.

20. Shladover SE, Tan SK. Analysis of Vehicle Positioning Accuracy Requirements for Communication-Based Cooperative Collision Warning. Journal of Intelligent Transportation Systems. 2006; 10(3): 131-140. doi: 10.1080/15472450600793610

21. Senthamil Selvan R, Analysis of EDFC and ADFC Algorithms for Secure Communication. Journal of Advanced Research in Dynamical and Control System. 2017; 9(18): 1171-1187.