A Hybrid Cryptosystem with MAC-Integrated Lattice-Based Quantum Encryption for Secure Communication in WBSNs

Authors

  • K.Gomathy Research Scholar, Department of Computer Science, VET Institute of Arts and Science (Co-education) College, Thindal, Erode, Tamil Nadu, India. https://orcid.org/0009-0007-4013-474X
  • K. S. Mohanasathiya Assistant Professor and Research Supervisor, Department of Computer Science, VET Institute of Arts and Science (Co-education) College, Thindal, Erode, Tamil Nadu, India. https://orcid.org/0009-0004-5897-602X

DOI:

https://doi.org/10.31838/NJAP/07.02.34

Keywords:

Hybrid Cryptosystem, Message Authentication Code, Improved Lattice-Based Quantum Cryptography, Wireless Body Sensor Networks, Post-Quantum Security, Data Integrity, Secure Communication, Key Exchange, Healthcare Security

Abstract

A wireless wearable human body sensor network. Sensor modules are implanted within the human body, on the body surface, and in garments to check the health of the patient at regular intervals for remote treatment and monitoring. Wireless Body Sensor Networks (WBSN) has applications such as healthcare, military, sports and remote treatment. It creates better quality human life with accurate, faster disease diagnosis and time-gap treatment and better treatment. The existing cryptographic protocols are plagued with the drawback of vulnerability to attacks and resource efficiency. The scheme under proposal was a combination of symmetric as well as asymmetric cryptographic protocols to provide an effective hybrid authentication for WBSN. Message Authentication Code (MAC) is a symmetric key cryptographic protocol for authentication of communicators' authentication. It has been deliberated in the proposed approach for authentication verification of authentic registration data. Enhanced Lattice-Based Quantum cryptography (ILBQC) is a cryptographic method which is asymmetric in order to verify human body sensed physiological data authentication. ILBQC is using a new in lattice quantum cryptography-based for generating keys, encryption, and decryption process. Thus, the proposed method uses plaintext partitioning, double encryption and decryption scheme in an attempt to validate secure authentication in WBSN. Performance of the suggested MAC-ILBQC method is measured in terms of key generation time, encryption time, decryption time, memory usage, overall execution time, energy expense, and resistance against attack.

References

1. Muthusamy, P., Kanagalakshmi, K., & BP, S. V. (2024). A Hybrid Improved Unequal Secure Cluster Based Distributed Routing Protocol with Quantum Key Distribution to Improve the Performance Measures in Wireless Body Sensor Network. INTERNATIONAL JOURNAL, 11(4), 407-427.

2. Prajapat, S., Kumar, P., & Kumar, S. (2024). A privacy preserving quantum authentication scheme for secure data sharing in wireless body area networks. Cluster Computing, 1–17.

3. Anilkumar, C., Lenka, S., Neelima, N., & Sathishkumar, V. E. (2024). A secure method of communication through BB84

protocol in quantum key distribution.Scalable Computing: Practice and Experience,25(1), 21–33.

4. SS, A., & Devprasad, K. D. (2024). Enhancing security in Wireless Body Area Networks (WBANs) with ECC-based Diffie-Hellman Key Exchange algorithm (ECDH). Technology and Health Care, 32(6), 4765-4784.

5. Dhanalakshmi, N., Atchaya, S., & Veeramani, R. (2015). A design of multiband antenna using main radiator and additional sub-patches for different wireless communication systems. International Journal of Communication and Computer Technologies, 3(1), 1–5. https://doi.org/10.31838/IJCCTS/03.01.01

6. Ismael, O. A., Kamil, A. T., Jasim, L. A., & JosephNg, P. S. (2024). Enhancing the performance of network in wireless body area network based on novel encryption algorithm. TELKOMNIKA (Telecommunication Computing Electronics and Control), 22(2), 340–350.

7. Arvinth, N. (2024). Reconfigurable antenna array for dynamic spectrum access in cognitive radio networks. National Journal of RF Circuits and Wireless Systems, 1(2), 1–6.

8. Guglielmi, A. V., Cisotto, G., Muraro, A., & Laurenti, N. Design of an Information Theoretic Key Agreement Protocol for WBANs Using Raw ECG.

9. Mejail, M., Nestares, B. K., & Gravano, L. (2024). The evolution of telecommunications: Analog to digital. Progress in Electronics and Communication Engineering, 2(1), 16–26. https://doi.org/10.31838/PECE/02.01.02

10. Kumari, S., & Tyagi, A. K. (2024). Wireless Sensor Networks: An Introduction. Digital Twin and Blockchain for Smart Cities, 495–528.

11. Sadulla, S. (2024). A comparative study of antenna design strategies for millimeter-wave wireless communication. SCCTS Journal of Embedded Systems Design and Applications, 1(1), 13–18. https://doi.org/10.31838/ESA/01.01.03

12. Hussain, A., Obaid, A. J., Tyagi, G., & Sharma, A. (Eds.). (2024). The Next Generation Innovation in IoT and Cloud Computing with Applications. CRC Press.

13. Mahmmod, B. M., Naser, M. A., Al-Sudani, A. H. S., Alsabah, M., Mohammed, H. J., Alaskar, H., ... & Abdulhussain, S. H. (2024). Patient monitoring system based on internet of things: A review and related challenges with open research issues. IEEE Access.

14. Herculano, J., Pereira, W., Guimarães, M., Cotrim, R., de Sá, A., Assis, F., ... & Gorender, S. (2024). MAC approaches to communication efficiency and reliability under dynamic network traffic in wireless body area networks: a review. Computing, 1–25.

15. Pande, S. D., & Khamparia, A. (Eds.). (2024). Networks Attack Detection on 5G Networks Using Data Mining Techniques. CRC Press.

16. Mariappan, D. B., Saminathan, R., & Baalamurugan, K. M. (2024). Secure patient data monitoring and efficient routing optimization using a hyperelliptic curve cryptography with fuzzy-based priority in WBSN. Recent Advances in Electrical & Electronic Engineering (Formerly Recent Patents on Electrical & Electronic Engineering), 17(7), 677–686.

17. Muniyandi, A. P., Balusamy, B., Dhanaraj, R. K., Sumathi, D., Nandakumar, S., Preetha, K. S., ... & Paramasivam, A. (2024). Intelligent Security System for Preventing DDoSAttacks for 6G Enabled WBSN using Improve Grey Wolf Optimization. IEEE Transactions on Consumer Electronics.

18. Jayasutha, D., Hemamalini, V., Sangeetha, S., & Yeruva, A. R. DIWGAN-WBSN: A novel health monitoring approach for wireless body sensor networks. International Journal of Communication Systems, e5934.

19. Verma, V., & Jha, V. K. (2024). Secure and energy-aware data transmission for IoT-WSNs with the help of cluster-based secure optimal routing.Wireless Personal Communications, 134(3), 1665–1686.

20. Mohanty, R. K., Sahoo, S. P., & Kabat, M. R. (2024). Thermal-energy-efficient-secured-link reliable and delay aware routing protocol (TESLDAR) for wireless body area networks. International Journal of Computers and Applications, 1–13.

21. Kaleem, M., &Devarajan, G. G. (2024). Energy-efficient classification strategy for detecting interference and malicious sensor nodes in wireless body area networks. Cyber Security and Applications,2, 100048.

22. Negra, R., Jemili, I., Zemmari, A., Mosbah, M., & Belghith, A. (2024). Investigating the impact of body node coordinator position on communication reliability in wireless body area networks. Network Modeling Analysis in Health Informatics and Bioinformatics, 13(1), 50.

23. Yuvaraja, M., Ramesh, R., Priya, R., & Dhanasekar, J. (2024). Wireless body sensor networks for real-time healthcare monitoring: A cost-effective and energy- efficient approach. Journal of Angiotherapy, 8(7), 1–13.

24. Mavinkattimath, S., Khanai, R., Torse, D., &Iyer, N. (2024). Design and implementation of low-power, highspeed, reliable and secured hardware accelerator using 28 nm technology for biomedical devices. Biomedical Signal Processing and Control, 88, 105554.

25. Al-Thobhani, N. G., & Sultan, J. (2024). The intelligence of WSNs. In Intelligent Wireless Sensor Networks and the Internet of Things (pp. 251–269). CRC Press.

26. Salika, F., Harb, H., Zaki, C., &Saux, E. (2024). MEDCO:

An efficient protocol for data compression in wireless

body sensor network. Journal of Ambient Intelligence and

Humanized Computing, 1–17.

27. Alawadhi, A., Almogahed, A., Mohammed, F., Ba-Quttayyan, B., & Hussein, A. (2024). Improving performance metrics in WBANs with a dynamic next beacon interval and superframe duration scheme. Heliyon, 10(5).

28. Ismael, O. A., Kamil, A. T., Jasim, L. A., & JosephNg, P. S. (2024). Enhancing the performance of network in wireless body area network based on novel encryption algorithm. TELKOMNIKA (Telecommunication Computing Electronics and Control), 22(2), 340–350.

29. Abdullah, A. M. (2024). Energy-efficient aware and predicting bandwidth estimation routing protocol for hybrid communication in wireless body area networks. Cluster Computing, 1–20.

30. Kumar, T. M. S. (2024). Low-power communication protocols for IoT-driven wireless sensor networks. Journal of Wireless Sensor Networks and IoT, 1(1), 37–43. https://doi.org/10.31838/WSNIOT/01.01.06

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Published

2025-10-31

Issue

Vol. 7 No. 2 (2025): NJAP

Section

Articles

How to Cite

K.Gomathy, & K. S. Mohanasathiya. (2025). A Hybrid Cryptosystem with MAC-Integrated Lattice-Based Quantum Encryption for Secure Communication in WBSNs. National Journal of Antennas and Propagation, 7(2), 262-275. https://doi.org/10.31838/NJAP/07.02.34

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