INTEGRATION OF QUANTUM KEY DISTRIBUTION INTO NEXT-GENERATION TELECOM SYSTEMS

Authors

  • Ergashova Durdona Khusniddin kizi Tashkent University of Information Technologies named after Muhammad al Khwarazmiy 3rd year student of the Faculty of Mobile Communication Technology

Keywords:

Quantum Key Distribution (QKD), BB84, E91, Quantum Cryptography · Telecom Security, Fiber-Optic Channels, Quantum Networks, QBER, Trusted Nodes, Quantum Repeaters

Abstract

As quantum computing threatens to compromise classical cryptographic systems, the need for future-proof, information-theoretically secure methods of communication has become critical. Quantum Key Distribution (QKD) leverages the fundamental principles of quantum mechanics to enable the secure generation and exchange of encryption keys, immune to computational attacks. This paper investigates the integration of QKD into telecom infrastructures to enable ultra-secure communication. We examine the performance of key QKD protocols, such as BB84 and E91, over fiber-optic and free-space channels, and simulate their deployment within realistic metropolitan network topologies. Results show that secure key rates of up to 10 kbps can be maintained over 50–80 km fiber links with Quantum Bit Error Rates (QBER) below 5%. The study also explores architecture models based on trusted relay nodes and WDM coexistence, highlighting practical deployment considerations. Our findings suggest that QKD is a viable enhancement for telecom security and a necessary foundation for long-term quantum-resilient communication systems.

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References

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Published

2026-04-01

How to Cite

Ergashova Durdona Khusniddin kizi. (2026). INTEGRATION OF QUANTUM KEY DISTRIBUTION INTO NEXT-GENERATION TELECOM SYSTEMS. Journal of Applied Science and Social Science, 16(4), 16–20. Retrieved from https://www.internationaljournal.co.in/index.php/jasass/article/view/3908

Issue

Vol. 16 No. 4 (2026): Journal of Applied Science and Social Science

Section

Articles

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