Rogov Boris Vadimovich

Publications in Math-Net.Ru

1. Accuracy of bicompact schemes in the problem of Taylor–Green vortex decay
   
   Zh. Vychisl. Mat. Mat. Fiz., 61:11 (2021),  1759–1778
2. Bicompact schemes for the multidimensional convection–diffusion equation
   
   Zh. Vychisl. Mat. Mat. Fiz., 61:4 (2021),  625–643
3. Bicompact schemes for gas dynamics problems: introducing complex domains using the free boundary method
   
   Computer Research and Modeling, 12:3 (2020),  487–504
4. Combined multidimensional bicompact scheme with higher order accuracy in domains of influence of nonstationary shock waves
   
   Dokl. RAN. Math. Inf. Proc. Upr., 494 (2020),  9–13
5. Combined monotone bicompact scheme of higher order accuracy in domains of influence of nonstationary shock waves
   
   Dokl. RAN. Math. Inf. Proc. Upr., 492 (2020),  79–84
6. Bicompact interpolation-characteristic scheme of the third order of approximation for the linear transport equation
   
   Keldysh Institute preprints, 2020, 106, 20 pp.
7. High-order bicompact schemes for numerical modelling of multispecies multi-reaction gas flows
   
   Mat. Model., 32:6 (2020),  21–36
8. On the accuracy of bicompact schemes as applied to computation of unsteady shock waves
   
   Zh. Vychisl. Mat. Mat. Fiz., 60:5 (2020),  884–899
9. Bicompact schemes for multidimensional hyperbolic equations on Cartesian meshes with solution-based AMR
   
   Keldysh Institute preprints, 2019, 011, 27 pp.
10. A conservative limiting method for bicompact schemes
    
    Keldysh Institute preprints, 2019, 008, 26 pp.
11. About the convergence and accuracy of the method of iterative approximate factorization of operators of multidimensional high-accuracy bicompact schemes
    
    Mat. Model., 31:12 (2019),  119–144
12. High-order bicompact schemes for shock-capturing computations of detonation waves
    
    Zh. Vychisl. Mat. Mat. Fiz., 59:8 (2019),  1381–1391
13. Two variants of parallel implementation of high-order accurate bicompact schemes for multi-dimensional inhomogeneous transport equation
    
    Keldysh Institute preprints, 2018, 177, 24 pp.
14. Dispersive and dissipative properties of the fully discrete bicompact schemes of the fourth order of spatial approximation for hyperbolic equations
    
    Keldysh Institute preprints, 2018, 153, 30 pp.
15. Family of symmetric bicompact schemes with spectral resolution property for hyperbolic equations
    
    Keldysh Institute preprints, 2018, 144, 28 pp.
16. On the convergence of the method of iterative approximate factorization of difference operators of high-order accurate bicompact scheme for nonstationary three-dimensional hyperbolic equations
    
    Keldysh Institute preprints, 2018, 132, 16 pp.
17. Iterative approximate factorization of difference operators of high-order accurate bicompact schemes for multidimensional nonhomogeneous quasilinear hyperbolic systems
    
    Zh. Vychisl. Mat. Mat. Fiz., 58:3 (2018),  313–325
18. A new hybrid scheme for computing discontinuous solutions of hyperbolic equations
    
    Keldysh Institute preprints, 2016, 022, 22 pp.
19. Optimal monotonization of a high-order accurate bicompact scheme for the nonstationary multidimensional transport equation
    
    Zh. Vychisl. Mat. Mat. Fiz., 56:6 (2016),  973–988
20. Minimal dissipation hybrid bicompact schemes for hyperbolic equations
    
    Zh. Vychisl. Mat. Mat. Fiz., 56:6 (2016),  958–972
21. Monotonization of high accuracy bicompact scheme for stationary multidimensional transport equation
    
    Mat. Model., 27:8 (2015),  32–46
22. Hybrid running schemes with upwind and bicompact symmetric differencing for hyperbolic equations
    
    Zh. Vychisl. Mat. Mat. Fiz., 55:7 (2015),  1196–1207
23. Uniqueness of a high-order accurate bicompact scheme for quasilinear hyperbolic equations
    
    Zh. Vychisl. Mat. Mat. Fiz., 54:5 (2014),  815–820
24. Bicompact scheme for linear inhomogeneous transport equation
    
    Mat. Model., 25:5 (2013),  55–66
25. High-order accurate monotone compact running scheme for multidimensional hyperbolic equations
    
    Zh. Vychisl. Mat. Mat. Fiz., 53:2 (2013),  264–274
26. About implementation of boundary conditions in the bicompact schemes for a linear transport equation
    
    Mat. Model., 24:10 (2012),  3–14
27. Monotone compact running schemes for systems of hyperbolic equations
    
    Zh. Vychisl. Mat. Mat. Fiz., 52:4 (2012),  672–695
28. Monotone high-precision compact scheme for quasilinear hyperbolic equations
    
    Mat. Model., 23:12 (2011),  65–78
29. The bicompact monotonic schemes for a multidimensional linear transport equation
    
    Mat. Model., 23:10 (2011),  107–116
30. The monotonic bicompact schemes for a linear transfer equation
    
    Mat. Model., 23:6 (2011),  98–110
31. Some aspects of compact difference scheme convergence
    
    Mat. Model., 20:1 (2008),  99–116
32. Hyperbolic-parabolic approximation of the Reynolds equations for turbulent flows of chemically reacting gas mixtures
    
    Mat. Model., 16:12 (2004),  20–39
33. Through marching method of calculation of transonic viscous flows
    
    Mat. Model., 16:5 (2004),  3–22
34. Method of minimum length for finding of critical parameters of mixed flows
    
    Mat. Model., 14:1 (2002),  87–96
35. Review of viscous internal flows models
    
    Mat. Model., 14:1 (2002),  41–72
36. On accuracy of the quasi-one-dimensional model of smooth wall channel
    
    Mat. Model., 13:10 (2001),  120–124
37. Marching method for calculating shock wave form in problems on supersonic inviscid flow past blunted bodies
    
    Mat. Model., 13:5 (2001),  110–118
38. Investigation of distribution of lithium atoms in the boundary layer of the flow of combustion products
    
    TVT, 38:5 (2000),  769–774
39. Relaxation of the composition of combustion products in cylindrical channels
    
    TVT, 38:4 (2000),  614–622
40. Investigation of the singularities of distribution of cesium atoms in the boundary layer of the flow of combustion products
    
    TVT, 38:1 (2000),  66–73
41. Two-stages marching method for calculation viscous flow through Laval nozzle
    
    Mat. Model., 11:7 (1999),  95–117
42. Method of direct Laval nozzle problem solution for turbulent flows of chemical-reacting gases
    
    Mat. Model., 10:1 (1998),  51–62
43. Nonequilibrium of concentration of carbon monoxide under conditions of interaction between a high-temperature flow of combustion products and a cooled plate
    
    TVT, 36:3 (1998),  470–474
44. Precise method for calculation of viscous flows in Lavale nozzle
    
    Mat. Model., 9:7 (1997),  81–92
45. $\mathrm{CO}$ relaxation in the combustion product flow in a channel with cold walls
    
    Dokl. Akad. Nauk, 349:3 (1996),  318–321
46. Quasionedimensional model of flows in smooth channels of variable section
    
    Mat. Model., 8:7 (1996),  3–10
47. Equations for the viscous flow in smooth ducts with variable cross sections
    
    Dokl. Akad. Nauk, 345:5 (1995),  615–618
48. Equations for viscous gas mixture flows in curved flat channels with variable cross section
    
    Mat. Model., 7:11 (1995),  39–54
49. Quasi-onedimentional model for chemical reacting flows in curved smooth cylindrical channels with variable cross section
    
    Mat. Model., 6:12 (1994),  38–56
50. The simulation of the boundary layer on a corundum wall in a flow of combustion products of propane-air with potassium seed: Theory and experiment
    
    TVT, 31:3 (1993),  411–417
51. Magnetohydrodynamic electric power station with thermochemical conversion of fuel. Technological scheme and thermal efficiency
    
    TVT, 30:3 (1992),  621–629
52. Снижение концентрации электронов в плазме продуктов сгорания вследствие образования отрицательных ионов
    
    TVT, 28:3 (1990),  620–622
53. Turbulent chemically reacting boundary-layer of gaseous combustion products with added potassium
    
    TVT, 25:6 (1987),  1144–1147
54. Saturation currents on electric probes in flows of a chemically reacting plasma with different types of ions
    
    TVT, 25:3 (1987),  573–581
55. Chemically nonequilibrium multicomponent boundary layer for a plasma of molecular gases with addition of alkali
    
    Prikl. Mekh. Tekh. Fiz., 27:5 (1986),  29–40
56. Effect of nonequilibrium chemical-reactions on the concentration distribution of alkali atoms in the boundary-layer of a combustion product plasma
    
    TVT, 24:3 (1986),  458–462
57. Saturation ion current to an electric probe in a slowly moving plasma
    
    Prikl. Mekh. Tekh. Fiz., 23:3 (1982),  5–13
58. Theoretical determination of saturation ion currents at an electric probe in subsonic plasma flux
    
    TVT, 19:5 (1981),  1031–1039