|
|
Publications in Math-Net.Ru |
Citations |
|
2023 |
1. |
T. A. Kudryashova, E. A. Galstyan, S. V. Polyakov, N. I. Tarasov, “Computer modeling of electron emission processes in strong electromagnetic fields”, Keldysh Institute preprints, 2023, 072, 16 pp. |
2. |
T. A. Kudryashova, S. V. Polyakov, N. I. Tarasov, “Numerical analysis of water purification processes in closed loop systems”, Matem. Mod., 35:3 (2023), 59–78 ; Math. Models Comput. Simul., 15:5 (2023), 817–831 |
3. |
T. A. Kudryashova, S. V. Polyakov, N. I. Tarasov, “Simulation of emission processes in strong electromagnetic fields”, Zh. Vychisl. Mat. Mat. Fiz., 63:8 (2023), 1354–1366 ; Comput. Math. Math. Phys., 63:8 (2023), 1486–1498 |
1
|
|
2022 |
4. |
N. I. Tarasov, T. A. Kudryashova, S. V. Polyakov, “Modeling formation and removal of limescale in water treatment systems”, Dokl. RAN. Math. Inf. Proc. Upr., 505 (2022), 79–85 ; Dokl. Math., 106:1 (2022), 279–285 |
2
|
5. |
T. A. Kudryashova, Yu. N. Karamzin, S. V. Polyakov, N. I. Tarasov, “Mathematical modeling of physical processes in electromagnetic water filters and heat exchangers”, Keldysh Institute preprints, 2022, 084, 24 pp. |
|
2021 |
6. |
S. V. Polyakov, T. A. Kudryashova, N. I. Tarasov, “Application of the multiscale approach to simulation of air sorbent filtration”, Dokl. RAN. Math. Inf. Proc. Upr., 500 (2021), 92–96 ; Dokl. Math., 104:2 (2021), 297–300 |
1
|
|
2020 |
7. |
S. V. Polyakov, T. A. Kudryashova, N. I. Tarasov, “Double potential method for modeling the internal flow of a viscous incompressible liquid”, Dokl. RAN. Math. Inf. Proc. Upr., 494 (2020), 76–79 ; Dokl. Math., 102:2 (2020), 418–421 |
2
|
8. |
S. V. Polyakov, Yu. N. Karamzin, T. A. Kudryashova, V. O. Podryga, D. V. Puzyrkov, N. I. Tarasov, “Multiscale supercomputer modeling of gas purification processes by the adsorption method”, Num. Meth. Prog., 21:1 (2020), 64–77 |
|
2019 |
9. |
N. I. Tarasov, S. V. Polyakov, Yu. N. Karamzin, T. A. Kudryashova, V. O. Podryga, D. V. Puzyrkov, “Incompressible viscous flow simulation using the quasi-hydrodynamic equations system”, Matem. Mod., 31:12 (2019), 33–43 ; Math. Models Comput. Simul., 12:4 (2020), 553–560 |
6
|
10. |
S. V. Polyakov, Yu. N. Karamzin, T. A. Kudryashova, V. O. Podryga, D. V. Puzyrkov, N. I. Tarasov, “Multiscale simulation of gas cleaning processes”, Matem. Mod., 31:9 (2019), 54–78 ; Math. Models Comput. Simul., 12:3 (2020), 302–315 |
|
2018 |
11. |
N. I. Tarasov, Yu. N. Karamzin, T. A. Kudryashova, S. V. Polyakov, “Incompressible viscous flow simulation using the double potential method”, Keldysh Institute preprints, 2018, 247, 20 pp. |
|
2016 |
12. |
S. V. Polyakov, Yu. N. Karamzin, T. A. Kudryashova, I. V. Tsybulin, “Exponential difference schemes for solution of boundary problems for diffusion-convection equations”, Matem. Mod., 28:7 (2016), 121–136 ; Math. Models Comput. Simul., 9:1 (2017), 71–82 |
6
|
|
2015 |
13. |
Yu. N. Karamzin, T. A. Kudryashova, V. O. Podryga, S. V. Polyakov, “Multiscale simulation of nonlinear processes in technical microsystems”, Matem. Mod., 27:7 (2015), 65–74 |
6
|
|
2010 |
14. |
S. V. Polyakov, T. A. Kudryashova, A. A. Sverdlin, E. M. Kononov, O. A. Kosolapov, “Parallel software package for modeling problems of continuous media mechanics on modern multiprocessor systems”, Matem. Mod., 22:6 (2010), 132–146 ; Math. Models Comput. Simul., 3:1 (2011), 46–57 |
2
|
|
2008 |
15. |
T. A. Kudryashova, S. V. Polyakov, E. M. Kononov, “Calculation of radiation in gas around reentry vehicle”, Matem. Mod., 20:10 (2008), 63–74 ; Math. Models Comput. Simul., 1:5 (2009), 551–560 |
2
|
16. |
T. A. Kudryashova, S. V. Polyakov, A. A. Sverdlin, “Calculation of gas flow parameters around reentry vehicle”, Matem. Mod., 20:7 (2008), 13–22 ; Math. Models Comput. Simul., 1:4 (2009), 445–452 |
12
|
|
2002 |
17. |
I. A. Graur, T. G. Elizarova, T. A. Kudryashova, S. V. Polyakov, “Numerical investigation of jet flows, using multiprocessor computer systems”, Matem. Mod., 14:6 (2002), 51–62 |
3
|
|
Organisations |
|
|
|
|