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Citations (Crossref Cited-By Service + Math-Net.Ru) |
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| 1. |
K. P. Belyaev, A. A. Kuleshov, N. P. Tuchkova, C. A. S. Tanajura, “An optimal data assimilation method and its application to the numerical simulation of the ocean dynamics”, Mathematical and Computer Modelling of Dynamical Systems, 2017 (Published online)    
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31
[x]
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| 2. |
K. P. Belyaev, A. A. Kuleshov, I. N. Smirnov, C. A. S. Tanajura, “Comparison of data assimilation methods into hydrodynamic models of ocean circulation”, Math. Models Comput. Simul., 11:4 (2019), 564–574  |
| 3. |
K. P. Belyaev, A. A. Kuleshov, N. P. Tuchkova, C. A. S. Tanajura, “A correction method for dynamic model calculations using observational data and its application in Oceanography”, Mathematical Models and Computer Simulations, 8:4 (2016), 391–400  |
| 4. |
B. N. Chetverushkin, N. G. Churbanova, A. A. Kuleshov, A. A. Lyupa, M. A. Trapeznikova, “Application of kinetic approach to porous medium flows simulation in environmental hydrology problems on high–performance computing systems”, Russian Journal of Numerical Analysis and Mathematical Modelling, 31:4 (2016), 187–196 
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8
[x]
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| 5. |
A. A. Kuleshov, E. E. Myshetskaya, S. E. Yakush, “Numerical simulation of forest fire propagation based on modified two–dimensional model”, Mathematical Models and Computer Simulations, 9:4 (2017), 437–447 |
| 6. |
A. A. Kuleshov, E. E. Myshetskaya, “Mathematical modeling of forest fires using two-dimensional multiphase models”, Matem. Mod., 17:1 (2005), 34–42 |
| 7. |
I. V. Belov, M. S. Bespalov, L. V. Klochkova, A. A. Kuleshov, D. V. Suzan, V. F. Tishkin, “Transport model of gas impurities spread in urban area”, Matem. Mod., 12:11 (2000), 38–46 |
| 8. |
V. E. Borisov, A. A. Kuleshov, E. B. Savenkov, S. E. Yakush, “TCS $\mathrm{3D}$ simulator: mathematical model”, Keldysh Institute preprints, 2015 |
| 9. |
A. A. Kuleshov, B. N. Chetverushkin, E. E. Myshetskaya, “Parallel computing in forest fire two-dimension modeling”, Computers and Fluids, 80 (2013), 202–206
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5
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| 10. |
A. A. Kuleshov, “Mathematical models of forest fires”, Matem. Mod., 14:11 (2002), 33–42 |
| 11. |
A. A. Kuleshov, E. E. Myshetskaya, “Mathematical modeling of forest fires using supercomputers”, Math. Models Comput. Simul., 1:5 (2009), 629–634 |
| 12. |
M. V. Alekseev, A. A. Kuleshov, E. B. Savenkov, “A mathematical model for impermeable porous media under thermomechanical loads”, Keldysh Institute preprints, 2017 |
| 13. |
A. A. Kuleshov, E. E. Myshetskaya, S. E. Yakush, “Two-dimensional three-phase mathematical model of forest fires”, Keldysh Institute preprints, 2017 |
| 14. |
M. V. Alekseev, A. A. Kuleshov, E. B. Savenkov, “Thermomechanical model for impermeable porous medium with chemically active filler”, Math. Models Comput. Simul., 10:4 (2018), 459–471 |
| 15. |
V. E. Borisov, A. A. Kuleshov, E. B. Savenkov, S. E. Yakush, “TCS 3D simulator: computational model”, Keldysh Institute preprints, 2015 |
| 16. |
A. A. Kuleshov, V. V. Mymrin, A. V. Razgulin, “Strong convergence of difference approximations in the problem of transverse vibrations of thin elastic plates”, Comput. Math. Math. Phys., 49:1 (2009), 146–171 |
| 17. |
A. A. Kuleshov, “Difference approximation of the problem of bending vibrations of a thin elastic plate”, Comput. Math. Math. Phys., 45:4 (2005), 694–715 |
| 18. |
K. P. Belyaev, A. A. Kuleshov, Yu. D. Resnyanskii, I. N. Smirnov, R. Yu. Fadeev, “Numerical experiments with the NEMO ocean circulation model and the assimilation of observational data from ARGO”, Matem. Mod., 35:3 (2023), 93–105 |
| 19. |
V. A. Balashov, E. B. Savenkov, A. A. Kuleshov, “Direct numerical simulation of a fluid flow in core samples based on quasi-hydrodynamic equations”, Proc. Int. Conf. of Computational Methods in Sciences and Engineering 2016, AIP Conference Proceedings, 1790, eds. T. E. Simos et al., American Institute of Physics, College Park, Maryland, U.S., 2016, 150006 
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2
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| 20. |
A. A. Kuleshov, “A difference approximation and regularization of a problem of optimal control of a process described by an elliptic equation”, Soviet Doklady Mathematics, 27:2 (1983), 427–432 |
| 21. |
E. V. Zipunova, A. A. Kuleshov, E. B. Savenkov, “Nonisothermal diffuse interface model for electrical breakdown channel
propagation”, Sib. Zh. Ind. Mat., 25:1 (2022), 39–53 |
| 22. |
A. A. Kuleshov, E. E. Myshetskaya, “Results of computation of the forest fires front propagation based on a two-dimensional three-phase model”, Keldysh Institute preprints, 2019 |
| 23. |
A. A. Kuleshov, E. E. Myshetskaya, “Numerical algorithm for two-dimensional three-phase mathematical model of forest fires”, Keldysh Institute preprints, 2018 |
| 24. |
A. A. Kuleshov, V. V. Mymrin, “Modeling of floating ice vibrations during plane landing on ice airdromes”, Vychisl. Metody Programm., 11:1 (2010), 7–13 |
| 25. |
A. A. Kuleshov, V. V. Mymrin, “Modelling of a floating ice vibrations as a thin elastic plate”, Matem. Mod., 21:6 (2009), 28–40 |
| 26. |
A. A. Kuleshov, “On a numerical method of the bending vibrations problem for thin elastic plave”, Matem. Mod., 17:4 (2005), 10–26 |
| 27. |
O. V. Dobrocheev, A. A. Kuleshov, N. P. Savenkova, S. V. Filippova, “2-D model of heavy gas dispersion over rough bedding surface”, Matem. Mod., 8:5 (1996), 91–105 |
| 28. |
K. P. Belyaev, A. A. Kuleshov, I. N. Smirnov, C. A. S.Tanajura, “Parallel assimilation of observed data in a hydrodynamic model of Ocean circulation”, Moscow University Computational Mathematics and Cybernetics, 41:2 (2017), 58–63 |
| 29. |
A. V. Kalmykov, A. A. Kuleshov, N. P. Savenkova, “Simulation of anode effect in aluminum electrolytic cell”, Keldysh Institute preprints, 2016 |
| 30. |
K. P. Belyaev, A. A. Kuleshov, N. P. Tuchkova, C. A. S. Tanajura, “On asymptotic distributions of analyses characteristics for the linear data assimilation problem”, Journal of Mathematical Sciences, 218:3 (2016), 245–256 |
| 31. |
K. P. Belyaev, A. A. Kuleshov, C. A. S. Tanajura, “An application of a data assimilation method based on the diffusion stochastic process theory using altimetry data in Atlantic”, Russian Journal of Numerical Analysis and Mathematical Modelling, 31:3 (2016), 137–148 |
| 32. |
K. Belyaev, A. Kuleshov, I. Kirchner, N. Tuchkova, “Numerical experiments with MPI-ESM coupled Atmosphere-Land-Ocean model in conjunction with data assimilations in Arctic Region”, Proc. Int. Conf. of Computational Methods in Sciences and Engineering 2016, AIP Conference Proceedings, 1790, eds. T. E. Simos et al., American Institute of Physics, College Park, Maryland, U.S., 2016, 150005 |
| 33. |
A. A. Kuleshov, E. E. Myshetskaya, S. E. Yakush, “Modified 2D model for prediction of forest fire spread”, International Journal of Environmental Science, 2016, no. 1, 28–33 |
| 34. |
B. N. Chetverushkin, A. A. Kuleshov, E. B. Savenkov, “Supercomputing challenges in mathematical modeling for petroleum industry”, Oil & Gas Field Engineering, 2014, no. 9, 38–47 |
| 35. |
V. V. Kozoderov, A. A. Kuleshov, “Forest fires modeling and observation of different stages of their development using hyperspectral airspace remote sensing data”, Issledovaniye Zemli iz kosmosa, 2012, no. 1, 29–39 |
| 36. |
A. A. Kuleshov, “Mathematical modeling of emergency situations with chemically hazardous gases”, Problemy analiza riska, 9:3 (2012), 42–47 |
| 37. |
A. A. Kuleshov, S. A. Vinogradova, “Three-dimensional two-phase mathematical model of forest fires”, Vestnik MEI, 2012, no. 6, 65–71 |
| 38. |
A. A. Kuleshov, “Numerical method for modeling of small transverse vibrations in thin elastic plates”, Zhurnal SVMO, 13:3 (2011), 66–72 |
| 39. |
A. Kuleshov, E. Myshetskaya, “Forest fires 2D numerical simulation”, Recent Researches in Mechanics, WSEAS Press, 2011, 77–82 |
| 40. |
A. A. Kuleshov, E. E. Myshetskaya, S. E. Yakush, “Two-dimensional two-phase mathematical models of forest fires”, Vestnik MEI, 2011, no. 6, 159–166 |
| 41. |
A. A. Kuleshov, N. M. Hidalgo Dias, G. M. Makhviladze, S. E. Yakush, “Modelling of industrial accidents with liquefied toxic and flammable gases”, Math. Models Comput. Simul., 2:6 (2010), 691–703 |
| 42. |
R. N. Kuz'min, A. A. Kuleshov, N. P. Savenkova, “Modeling of impact lunar craters”, Matem. Mod., 15:2 (2003), 83–88 |
| 43. |
R. N. Kuz'min, A. A. Kuleshov, N. P. Savenkova, S. V. Filippova, “Modelling of heavy gas cloud dispersion under industrial accidents”, Matem. Mod., 10:8 (1998), 33–42 |
| 44. |
A. A. Kuleshov, “Necessary conditions for optimality in an optimal control problem for a mixed system”, Soviet Doklady Mathematics, 26:1 (1982), 145–149 |
| 45. |
R. Yu. Fadeev, K. P. Belyaev, A. A. Kuleshov, Yu. D. Resnyanskii, I. N. Smirnov, B. S. Strukov, A. A. Zelenko, “Numerical experiments with SLAV-NEMO atmosphere-ocean coupled model”, Matem. Mod., 36:4 (2024), 116–132 |
| 46. |
K. P. Belyaev, A. A. Kuleshov, I. N. Smirnov, “Analysis of the results of ocean dynamics modeling using various methods of assimilation of observational data”, Keldysh Institute preprints, 2018 |
| 47. |
K. P. Belyaev, A. A. Kuleshov, N. P. Tuchkova, “Modeling of ocean dynamics in conjunction with data assimilation”, Keldysh Institute preprints, 2018 |
| 48. |
M. V. Alekseev, A. A. Kuleshov, N. G. Sudobin, E. B. Savenkov, “Mathematical modelling of thermomechanical behaviour of impermeable porous media”, Keldysh Institute preprints, 2018 |
| 49. |
A. A. Kuleshov, Informatsionnye Tekhnologii i Vychslitel'nye Sistemy, 2003, no. 4, 56–70 |
| 50. |
A. A. Kuleshov, “Necessary conditions for optimality in an optimal control problem for a mixed system”, Dokl. Akad. Nauk SSSR, 265:4 (1982), 805–809 |
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