D. 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. Rev. A, 101:3 (2020), 32334
N. R. Kenbaev, D. A. Kronberg, “Quantum postselective measurements: Sufficient condition for overcoming the Holevo bound and the role of max-relative entropy”, Phys. Rev. A, 105:1 (2022), 012609
D. A. Kronberg, “Success probability for postselective transformations of pure quantum states”, Phys. Rev. A, 106:4 (2022), 42447
D. A. Kronberg, “Uyazvimost kvantovoi kriptografii s fazovo-vremenným kodirovaniem v usloviyakh zatukhaniya”, TMF, 214:1 (2023), 140–152
A. D. Kodukhov, D. A. Kronberg, “Entanglement-based approach to quantum coherence, path information, and uncertainty”, Phys. Rev. A, 108 (2023), 052429
I. A. Zhigal'skii, D. A. Kronberg, “Eavesdropping strategy for quantum cryptography protocol with phase-time encoding in multiphoton case”, TMF (to appear)
2024
2.
D. A. Kronberg, “On the Structure of Postselective Transformations of Quantum States”, Proc. Steklov Inst. Math., 324 (2024), 123–134
3.
G. G. Amosov, A. D. Baranov, D. A. Kronberg, “On positive operator-valued measures generated by a family of one-dimensional projectors”, Ann. Funct. Anal., 15 (2024), 48 , 12 pp. ;
4.
D. A. Kronberg, “A quantum scheme for attack on a phase-time encoded quantum cryptography protocol”, Mat. Vopr. Kriptogr., 15:2 (2024), 91–100
5.
T. R. Klevtsov, D. A. Kronberg, “On eavesdropping strategy for geometrically uniform coherent states quantum cryptography protocol”, Lobachevskii J. Math., 45:6 (2024), 2527–2533;
2023
6.
D. A. Kronberg, “Vulnerability of quantum cryptography with phase–time coding under attenuation conditions”, Theoret. and Math. Phys., 214:1 (2023), 121–131
7.
A. S. Avanesov, D. A. Kronberg, “On postselective modifications of quantum observables”, Lobachevskii J. Math., 44:6 (2023), 1980–1989;
V. A. Pastushenko, D. A. Kronberg, “On classical data processing which affects additivity of quantum accessible information”, Lobachevskii J. Math., 44:6 (2023), 2160–2168;
A. D. Kodukhov, D. A. Kronberg, “Entanglement-based approach to quantum coherence, path information, and uncertainty”, Phys. Rev. A, 108 (2023), 052429 , 9 pp. ;
10.
Timur Klevtsov, Dmitry Kronberg, “Assisted postselective quantum transformations and an improved photon number splitting attack strategy”, Mathematics, 11:24 (2023), 4973 , 11 pp. ;
N. R. Kenbaev, D. A. Kronberg, “Quantum postselective measurements: Sufficient condition for overcoming the Holevo bound and the role of max-relative entropy”, Phys. Rev. A, 105:1 (2022), 12609 , 6 pp. ;
D. 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. Molotkov, K. S. Kravtsov, and M. I. Ryzhkin and on the Erratum to This Paper”, J. Exp. Theor. Phys., 134:5 (2022), 533–535
13.
D. Babukhin, D. Kronberg, D. Sych, “Explicit attacks on the Bennett-Brassard 1984 protocol with partially distinguishable photons”, Phys. Rev. A, 106 (2022), 042403 , 9 pp., arXiv: 2205.15964;
D. A. Kronberg, “Modification of Quantum Measurements by Mapping onto Quantum States and Classical Outcomes”, Lobachevskii J. Math., 43:7 (2022), 1663–1668;
A. S. Trushechkin, E. O. Kiktenko, D. A. Kronberg, A. K. Fedorov, “Security of the decoy state method for quantum key distribution”, Phys. Usp., 64:1 (2021), 88–102
17.
D. A. Kronberg, “Increasing the Distinguishability of Quantum States with an Arbitrary Success Probability”, Proc. Steklov Inst. Math., 313 (2021), 113–119
18.
N. R. Kenbaev, D. A. Kronberg, “Quantum measurement with post-selection for two mixed states”, AIP Conf. Proc., 2362, 2021, 050001 , 5 pp. ;
19.
A. B. Sagingalieva, D. A. Kronberg, “Adaptive algorithms of error correction and error estimation in quantum cryptography”, AIP Conf. Proc., 2362, 2021, 050002 , 8 pp. ;
D. A. Kronberg, “Vulnerabilities of quantum cryptography on geometrically uniform coherent states”, Quantum Electronics, 51:10 (2021), 928–937
23.
A. D. Kodukhov, V. A. Pastushenko, N. S. Kirsanov, D. A. Kronberg, V. M. Vinokur, M. Pflitsch, G. B. Lesovik, Boosting quantum key distribution via the end-to-end physical control, 2021 , 14 pp., arXiv: 2109.05575
24.
V. Rodimin, A. Tayduganov, D. Kronberg, Y. Durkin, A. Zharinov, Y. Kurochkin, Go-and-return phase encoded SR QKD and its security consideration, 2021 , 15 pp., arXiv: 2106.10082
25.
A. S. Avanesov, D. A. Kronberg, “On eavesdropping strategy for symmetric coherent states quantum cryptography using heterodyne measurement”, Lobachevskii J. Math., 42:10 (2021), 2285–2294;
N. S. Kirsanov, N. R. Kenbaev, A. B. Sagingalieva, D. A. Kronberg, V. M. Vinokur, G. B. Lesovik, Long-distance quantum key distribution based on the physical loss control, 2021 , 20 pp., arXiv: 2105.00035
2020
27.
D. 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. Rev. A, 101:3 (2020), 32334 , 7 pp., arXiv: 1910.06167;
A. S. Avanesov, D. A. Kronberg, “Possibilities of using practical limitations of an eavesdropper in quantum cryptography”, Quantum Electronics, 50:5 (2020), 454–460
29.
D. A. Kronberg, “Role of collective preparation and measurement of states in some quantum communication protocols”, Quantum Electronics, 50:5 (2020), 461–468
30.
A. S. Avanesov, D. A. Kronberg, “On applying pseudorandom number generators in quantum cryptography with coherent states”, AIP Conf. Proc., 2241, 2020, 20026 , 4 pp. ;
31.
D. A. Kronberg, “Generalized discrimination between symmetric coherent states for eavesdropping in quantum cryptography”, Lobachevskii J. Math., 41:12 (2020), 2332–2337;
A. S. Avanesov, D. A. Kronberg, A. N. Pechen, “Active beam splitting attack applied to differential phase shift quantum key distribution protocol”, P-Adic Numbers Ultrametric Anal. Appl., 10:3 (2018), 222–232 , arXiv: 1910.08339
D. A. Kronberg, Yu. V. Kurochkin, “Role of intensity fluctuations in quantum cryptography with coherent states”, Quantum Electron., 48:9 (2018), 843–848
2017
36.
D. A. Kronberg, E. O. Kiktenko, A. K. Fedorov, Yu. V. Kurochkin, “Analysis of coherent quantum cryptography protocol vulnerability to an active beam-splitting attack”, Quantrum Electron., 47:2 (2017), 163–168
37.
D. A. Kronberg, “New methods of error correction in quantum cryptography using low-density parity-check codes”, Matem. vopr. kriptogr., 8:2 (2017), 77–86
D. A. Kronberg, S. N. Molotkov, “Duality of quantum communication channels and a collective intercept-resend attack on quantum key distribution with differential phase shift”, JETP Letters, 100:4 (2014), 279–284
39.
D. A. Kronberg, S. N. Molotkov, “On a beam splitter attack and soft filtering of coherent states in differential phase shift quantum cryptography”, Journal of Experimental and Theoretical Physics, 118:1 (2014), 1–10
40.
D. A. Kronberg, “A simple coherent attack and practical security of differential phase shift quantum cryptography”, Laser Physics, 24:2 (2014), 025202 , 4 pp.
D. A. Kronberg, “Rasshirenie oblasti sekretnosti protokola kvantovogo raspredeleniya klyuchei s fazovo-vremennym kodirovaniem”, Sbornik statei molodykh uchenykh fakulteta VMK MGU, Izdatelskii otdel fakulteta VMK MGU, 2011, 69–82
D. A. Kronberg, S. N. Molotkov, “Enhancement of the robustness of phase-time quantum cryptography by block error correction”, JETP Letters, 92:7 (2010), 490–495
46.
D. A. Kronberg, S. N. Molotkov, “Quantum scheme for an optimal attack on quantum key distribution protocol BB84”, Bulletin of the Russian Academy of Sciences: Physics, 74:7 (2010), 912–918
47.
D. A. Kronberg, S. N. Molotkov, “Quantum circuit for optimal eavesdropping in quantum key distribution using phase-time coding”, Journal of Experimental and Theoretical Physics, 111:1 (2010), 27–56
2009
48.
D. A. Kronberg, S. N. Molotkov, “Quantum key distribution in a single-photon regime with nonorthogonal basis states”, JETP Letters, 89:7 (2009), 370–376
49.
D.A. Kronberg, S.N.Molotkov, “Security of a two-parameter quantum cryptography system using time-shifted states against photon-number splitting attacks”, Journal of Experimental and Theoretical Physics, 109:4 (2009), 557–584
2024
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