![]() ![]() Math., 41:12 (2020), 2332–2337 (cited: 5) (cited: 6) Ī. S. Avanesov, D. A. Kronberg, “Coherent-state quantum cryptography using pseudorandom number generators”, Quantum Electronics, 49:10 (2019), 974–981 (cited: 5) (cited: 5)ĭ. A. Kronberg, “Coherence of quantum ensemble as a dual to uncertainty for a single observable”, Lobachevskii J. ĭ. A. Kronberg, “Generalized discrimination between symmetric coherent states for eavesdropping in quantum cryptography”, Lobachevskii J. ![]() Kronberg, “Role of collective preparation and measurement of states in some quantum communication protocols”, Quantum Electronics, 50:5 (2020), 461–468Ī. S. Avanesov, D. A. Kronberg, “On applying pseudorandom number generators in quantum cryptography with coherent states”, AIP Conf. Kronberg, “Possibilities of using practical limitations of an eavesdropper in quantum cryptography”, Quantum Electronics, 50:5 (2020), 454–460 (cited: 2) (cited: 2)ĭ. Lesovik, Long-distance quantum key distribution based on the physical loss control, 2021, 20 pp., arXiv: 2105.00035ĭ. A. Kronberg, A. S. Nikolaeva, Yu. V. Kurochkin, A. K. Fedorov, “Quantum soft filtering for the improved security analysis of the coherent one-way quantum-key-distribution protocol”, Phys. Kurochkin, Go-and-return phase encoded SR QKD and its security consideration, 2021, 15 pp., arXiv: 2106.10082Ī. S. Avanesov, D. A. Kronberg, “On eavesdropping strategy for symmetric coherent states quantum cryptography using heterodyne measurement”, Lobachevskii J. Lesovik, Boosting quantum key distribution via the end-to-end physical control, 2021, 14 pp., arXiv: 2109.05575 Kronberg, “Vulnerabilities of quantum cryptography on geometrically uniform coherent states”, Quantum Electronics, 51:10 (2021), 928–937Ī. ĭ. A. Kronberg, “Comment on “Practical quantum key distribution with geometrically uniform states””, Phys. Īlexey Kodukhov, Dmitry Kronberg, “Measuring entangled state: On connection between observable uncertainty and ensemble coherence”, AIP Conf. (cited: 1) Ī. B. Sagingalieva, D. A. Kronberg, “Adaptive algorithms of error correction and error estimation in quantum cryptography”, AIP Conf. N. R. Kenbaev, D. A. Kronberg, “Quantum measurement with post-selection for two mixed states”, AIP Conf. Usp., 64:1 (2021), 88–102 (cited: 5) (cited: 4)ĭ. A. Kronberg, “Increasing the Distinguishability of Quantum States with an Arbitrary Success Probability”, Proc. Phys., 134:5 (2022), 533–535Ī. S. Trushechkin, E. O. Kiktenko, D. A. Kronberg, A. K. Fedorov, “Security of the decoy state method for quantum key distribution”, Phys. Ryzhkin and on the Erratum to This Paper”, J. ![]() ĭ. A. Kronberg, E. O. Kiktenko, A. S. Trushechkin, A. K. Fedorov, “Comments on the Paper “Are There Enough Decoy States to Ensure Key Secrecy in Quantum Cryptography?” by S. N. R. Kenbaev, D. A. Kronberg, “Quantum postselective measurements: Sufficient condition for overcoming the Holevo bound and the role of max-relative entropy”, Phys. D. A. Kronberg, “Vulnerability of quantum cryptography with phase-time coding under channel attenuation”, TMF (to appear) ![]()
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