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Kronberg Dmitry Anatolevich
(recent publications)
| by years | scientific publications | by types |

1. 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”, Journal of Experimental and Theoretical Physics, 134:5 (2022), 533–535  crossref  crossref  scopus
2. 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.  mathnet  crossref  isi  scopus;

3. 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  mathnet  crossref  crossref  adsnasa  isi (cited: 5)  elib  scopus (cited: 4)
4. D. A. Kronberg, “Increasing the Distinguishability of Quantum States with an Arbitrary Success Probability”, Proc. Steklov Inst. Math., 313 (2021), 113–119  mathnet  crossref  crossref  isi (cited: 2)  elib  scopus (cited: 2)
5. N. R. Kenbaev, D. A. Kronberg, “Quantum measurement with post-selection for two mixed states”, AIP Conf. Proc., 2362, 2021, 050001 , 5 pp.  mathnet  crossref  scopus (cited: 1);
6. 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.  mathnet  crossref  scopus;
7. Alexey Kodukhov, Dmitry Kronberg, “Measuring entangled state: On connection between observable uncertainty and ensemble coherence”, AIP Conf. Proc., 2362, 2021, 050003 , 7 pp.  mathnet  crossref  scopus;
8. D. A. Kronberg, “Comment on “Practical quantum key distribution with geometrically uniform states””, Phys. Rev. A, 104:2 (2021), 026401 , 3 pp.  mathnet  crossref  adsnasa  isi  scopus;
9. D. A. Kronberg, “Vulnerabilities of quantum cryptography on geometrically uniform coherent states”, Quantum Electronics, 51:10 (2021), 928–937  mathnet  crossref  adsnasa  isi  elib  scopus
10. 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
11. 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
12. 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  mathnet  crossref  mathscinet  isi (cited: 1)  scopus (cited: 1);
13. 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

14. 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  mathnet  crossref  mathscinet  adsnasa  isi (cited: 9)  scopus (cited: 11);  mathscinet
15. A. S. Avanesov, D. A. Kronberg, “Possibilities of using practical limitations of an eavesdropper in quantum cryptography”, Quantum Electronics, 50:5 (2020), 454–460  mathnet  crossref  adsnasa  isi (cited: 2)  elib  scopus (cited: 2)
16. D. A. Kronberg, “Role of collective preparation and measurement of states in some quantum communication protocols”, Quantum Electronics, 50:5 (2020), 461–468  mathnet  crossref  adsnasa  isi  elib  scopus
17. 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.  mathnet  crossref  isi  scopus;
18. D. A. Kronberg, “Generalized discrimination between symmetric coherent states for eavesdropping in quantum cryptography”, Lobachevskii J. Math., 41:12 (2020), 2332–2337  mathnet  crossref  mathscinet  isi (cited: 5)  elib  scopus (cited: 6);  mathscinet

19. A. S. Avanesov, D. A. Kronberg, “Coherent-state quantum cryptography using pseudorandom number generators”, Quantum Electronics, 49:10 (2019), 974–981  mathnet  crossref  mathscinet  mathscinet  adsnasa  isi (cited: 5)  elib  scopus (cited: 5)
20. D. A. Kronberg, “Coherence of quantum ensemble as a dual to uncertainty for a single observable”, Lobachevskii J. Math., 40:10 (2019), 1507–1515  mathnet  crossref  mathscinet  zmath  isi (cited: 2)  scopus (cited: 3)

21. 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  mathnet  crossref  mathscinet  isi (cited: 11)  scopus (cited: 11)
22. D. A. Kronberg, Yu. V. Kurochkin, “Role of intensity fluctuations in quantum cryptography with coherent states”, Quantum Electron., 48:9 (2018), 843–848  mathnet  mathnet  crossref  adsnasa  isi (cited: 9)  elib  elib  scopus (cited: 9)

23. 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  mathnet  crossref  mathscinet  adsnasa  isi (cited: 7)  elib  scopus (cited: 7)
24. 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  mathnet (cited: 3)  crossref  mathscinet  elib

25. 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  mathnet  crossref  crossref  adsnasa  isi (cited: 3)  elib (cited: 1)  elib (cited: 1)  scopus (cited: 3)
26. 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  mathnet  crossref  crossref  adsnasa  isi (cited: 3)  elib  scopus (cited: 2)
27. D. A. Kronberg, “A simple coherent attack and practical security of differential phase shift quantum cryptography”, Laser Physics, 24:2 (2014), 025202 , 4 pp.  mathnet  crossref  adsnasa  isi (cited: 6)  scopus (cited: 7)

28. 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
29. D. A. Kronberg, Yu. I. Ozhigov, A. Yu. Chernyavskii, Kvantovaya kriptografiya, Maks Press, Moskva, 2011 , 112 pp. http://sqi.cs.msu.su/store/storage/ss8dw5n_quantum_cryptography.pdf
30. D. A. Kronberg, Yu. I. Ozhigov, A. Yu. Chernyavskii, Kvantovaya informatika i kvantovyi kompyuter, Maks Press, Moskva, 2011 , 68 pp. http://sqi.cs.msu.su/store/storage/th25kzj_quantum_computer.pdf
31. D. A. Kronberg, Yu. I. Ozhigov, A. Yu. Chernyavskii, Algebraicheskii apparat kvantovoi informatiki, Maks Press, Moskva, 2011 , 56 pp. http://sqi.cs.msu.su/store/storage/jpvtv20_algebraic_tools.pdf

32. 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  mathnet  crossref  adsnasa  isi  elib  scopus
33. 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  crossref  zmath  adsnasa  scopus (cited: 2)
34. 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  crossref  adsnasa  isi (cited: 3)  elib  scopus (cited: 2)

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