Security assessment and improvement of smart grid NIKE protocol (original) (raw)

References

1. Benmalek, M., Challal, Y.: Mk-ami: efficient multi-group key management scheme for secure communications in AMI systems. In: 2016 IEEE Wireless Communications and Networking Conference, pp. 1–6. IEEE, (2016)
2. Anzalchi, A., Sarwat, A.: A survey on security assessment of metering infrastructure in smart grid systems. In: SoutheastCon 2015, pp. 1–4. IEEE, (2015)
3. Mohammed, A., George, G.: Vulnerabilities and strategies of cybersecurity in smart grid-evaluation and review. In: 2022 3rd International Conference on Smart Grid and Renewable Energy (SGRE), pp. 1–6. IEEE, (2022)
4. Mohammadali, A., Haghighi, M.S., Tadayon, M.H., Mohammadi-Nodooshan, A.: A novel identity-based key establishment method for advanced metering infrastructure in smart grid. IEEE Trans. Smart Grid 9(4), 2834–2842 (2018)
   Article Google Scholar
5. Dapeng, W., Zhou, C.: Fault-tolerant and scalable key management for smart grid. IEEE Trans. Smart Grid 2(2), 375–381 (2011)
   Article Google Scholar
6. Xia, J., Wang, Y.: Secure key distribution for the smart grid. IEEE Trans. Smart Grid 3(3), 1437–1443 (2012)
   Article Google Scholar
7. Park, J.H., Kim, M., Kwon, D.: Security weakness in the smart grid key distribution scheme proposed by Xia and Wang. IEEE Trans. Smart Grid 4(3), 1613–1614 (2013)
   Article Google Scholar
8. Liu, N., Chen, J., Zhu, L., Zhang, J., He, Y.: A key management scheme for secure communications of advanced metering infrastructure in smart grid. IEEE Trans Indus Electr 60(10), 4746–4756 (2012)
   Article Google Scholar
9. Wan, Z., Wang, G., Yang, Y., Shi, S.: Skm: scalable key management for advanced metering infrastructure in smart grids. IEEE Trans. Indus. Electr. 61(12), 7055–7066 (2014)
   Article Google Scholar
10. Tsai, J.-L., Lo, N.-W.: Secure anonymous key distribution scheme for smart grid. IEEE Trans. Smart Grid 7(2), 906–914 (2015)
    Google Scholar
11. Canetti, R., Krawczyk, H.: Analysis of key-exchange protocols and their use for building secure channels. In: Advances in Cryptology—EUROCRYPT 2001: International Conference on the Theory and Application of Cryptographic Techniques Innsbruck, Austria, May 6–10, 2001 Proceedings 20, pp. 453–474. Springer, (2001)
12. Odelu, V., Das, A.K., Goswami, A.: A secure biometrics-based multi-server authentication protocol using smart cards. IEEE Trans. Inf. Foren. Secur. 10(9), 1953–1966 (2015)
    Article Google Scholar
13. Odelu, V., Das, A.K., Wazid, M., Conti, M.: Provably secure authenticated key agreement scheme for smart grid. IEEE Trans. Smart Grid 9(3), 1900–1910 (2016)
    Google Scholar
14. Mahmood, K., Chaudhry, S.A., Naqvi, H., Kumari, S., Li, X., Sangaiah, A.K.: An elliptic curve cryptography based lightweight authentication scheme for smart grid communication. Fut. Gener. Comput. Syst. 81, 557–565 (2018)
    Article Google Scholar
15. Zhang, L., Zhao, L., Yin, S., Chi, C.-H., Liu, R., Zhang, Y.: A lightweight authentication scheme with privacy protection for smart grid communications. Fut. Gener. Comput. Syst. 100, 770–778 (2019)
    Article Google Scholar
16. Kumar, P., Gurtov, A., Sain, M., Martin, A., Phuong, H.H.: Lightweight authentication and key agreement for smart metering in smart energy networks. IEEE Trans. Smart Grid 10(4), 4349–4359 (2018)
    Article Google Scholar
17. Khan, A.A., Kumar, V., Ahmad, M., Rana, S., Mishra, D.: Palk: Password-based anonymous lightweight key agreement framework for smart grid. Int. J. Electr. Power Energy Syst. 121, 106121 (2020)
    Article Google Scholar
18. Chaudhry, S.A.: Correcting palk: password-based anonymous lightweight key agreement framework for smart grid. Int. J. Electr. Power Energy Syst. 125, 106529 (2021)
    Article Google Scholar
19. Nyangaresi, V.O., Mohammad, Z.: Privacy preservation protocol for smart grid networks. In: 2021 International Telecommunications Conference (ITC-Egypt), pp. 1–4. IEEE, (2021)
20. Srinivas, J., Das, A.K., Li, X., Khan, M.K., Jo, M.: Designing anonymous signature-based authenticated key exchange scheme for internet of things-enabled smart grid systems. IEEE Trans. Indus. Inf. 17(7), 4425–4436 (2020)
    Article Google Scholar
21. Khan, A.A., Kumar, V., Ahmad, M., Rana, S.: Lakaf: lightweight authentication and key agreement framework for smart grid network. J. Syst. Archit. 116, 102053 (2021)
22. Baghestani, S.H., Moazami, F., Tahavori, M.: Lightweight authenticated key agreement for smart metering in smart grid. IEEE Syst. J. 16(3), 4983–4991 (2022)
    Article Google Scholar
23. Chai, S., Yin, H., Xing, B., Li, Z., Guo, Y., Zhang, D., Zhang, X., He, D., Zhang, J., Yu, X., et al.: Provably secure and lightweight authentication key agreement scheme for smart meters. IEEE Transactions on Smart Grid, (2023)
24. Ratzer, A.V., et al.: Cpn tools for editing, simulating, and analysing coloured petri nets. In: Applications and Theory of Petri Nets 2003: 24th International Conference, ICATPN 2003 Eindhoven, The Netherlands, June 23–27, 2003 Proceedings, pp. 450–462. Springer (2003)
25. Attia, H.B., Kahloul, L., Benhazrallah, S., Bourekkache, S.: Using hierarchical timed coloured petri nets in the formal study of TRBAC security policies. Int. J. Inf. Secur. 19(2), 163–187 (2020)
    Article Google Scholar
26. Yankson, B.: Continuous improvement process (CIP)-based privacy-preserving framework for smart connected toys. Int. J. Inf. Secur. 20(6), 849–869 (2021)
    Article Google Scholar
27. Gong, X., Feng, T.: Lightweight anonymous authentication and key agreement protocol based on COAP of internet of things. Sensors 22(19), 7191 (2022)
    Article Google Scholar
28. Sakurada, H.: Security evaluation of the plaid protocol using the proverif tool. NTT Commun. Sci. Lab. (2013)
29. Meier, S., Schmidt, B., Cremers, C., Basin, D.: The tamarin prover for the symbolic analysis of security protocols. In: Computer Aided Verification: 25th International Conference, CAV 2013, Saint Petersburg, Russia, July 13–19, 2013. Proceedings 25, pp. 696–701. Springer, (2013)
30. Dolev, D., Yao, A.: On the security of public key protocols. IEEE Trans. Inf. Theory 29(2), 198–208 (1983)
    Article MathSciNet Google Scholar
31. Abbasinezhad-Mood, D., Ostad-Sharif, A., Nikooghadam, M., Mazinani, S.M.: A secure and efficient key establishment scheme for communications of smart meters and service providers in smart grid. IEEE Trans. Indus. Inf. 16(3), 1495–1502 (2019)
    Article Google Scholar

Download references