Abalakin Ilya Vladimirivich

Publications in Math-Net.Ru

1. Generalized Brinkman volume penalization method for compressible flows around moving obstacles
   
   Matem. Mod., 34:2 (2022),  41–57
2. Simulation of flow near rotating propeller on adaptive unstructured meshes using immersed boundary method
   
   Matem. Mod., 33:8 (2021),  59–82
3. Characteristic based volume penalization method for numerical simulation of compressible flows on unstructured meshes
   
   Zh. Vychisl. Mat. Mat. Fiz., 61:8 (2021),  1336–1352
4. Method for prediction of aerodynamic characteristics of helicopter rotors based on edge-based schemes in code NOISEtte
   
   Computer Research and Modeling, 12:5 (2020),  1097–1122
5. About solid walls boundary conditions for viscous flow problems
   
   Matem. Mod., 32:11 (2020),  79–98
6. Parallel algorithm for flow simulation in rotor-stator systems based on edge-bases schemes
   
   Matem. Mod., 32:6 (2020),  127–140
7. Numerical simulation of acoustic fields induced by flow past oscillating solid
   
   Matem. Mod., 31:10 (2019),  98–116
8. Immersed boundary method on deformable unstructured meshes for airfoil aeroacoustic simulation
   
   Zh. Vychisl. Mat. Mat. Fiz., 59:12 (2019),  2046–2059
9. Multimodel approach for helicopter rotor aeroacoustic and aerodynamic characteristics modeling using numerical simulation
   
   Keldysh Institute preprints, 2018, 047, 32 pp.
10. Simulation of unsteady turbulent flow around a cylinder prescribed by immersed boundary method
    
    Matem. Mod., 30:5 (2018),  117–133
11. Simulation of aerodynamics of a moving body prescribed by immersed boundaries on dynamically adaptative unstructured mesh
    
    Matem. Mod., 30:5 (2018),  57–75
12. Immersed boundary method for numerical simulation of inviscid compressible flows
    
    Zh. Vychisl. Mat. Mat. Fiz., 58:9 (2018),  1462–1471
13. Implementation the low Mach number method for calculation of flows in the software package NOISEtte
    
    Matem. Mod., 29:4 (2017),  101–112
14. Reconstruction of body geometry on unstructured meshes when using immersed boundary method
    
    Matem. Mod., 28:6 (2016),  77–88
15. Numerical simulation of aerodynamic and acoustic characteristics of rotor in ring
    
    Matem. Mod., 27:10 (2015),  125–144
16. The implementation of immersed boundary method for simulation of external flow on unstructured meshes
    
    Matem. Mod., 27:10 (2015),  5–20
17. Using Brinkman penalization method for numerical simulation viscous compressible flows over obstacles
    
    Keldysh Institute preprints, 2014, 011, 14 pp.
18. Higher accuracy scheme based on edge-oriented quasi-1В reconstruction of variables for solving aerodynamics and aeroacoustics problems on unstructured meshes
    
    Matem. Mod., 25:8 (2013),  109–136
19. Parallel research code NOISEtte for large-scale CFD and CAA simulations
    
    Num. Meth. Prog., 13:3 (2012),  110–125
20. Numerical experiments on acoustic liners
    
    Matem. Mod., 19:8 (2007),  15–21
21. Study of impact of viscous-terms approximation on accuracy of numerical solution of gas dynamics equations
    
    Matem. Mod., 19:7 (2007),  85–92
22. High accuracy scheme for solving nonlinear aeroacoustics problems on unstructured meshes
    
    Matem. Mod., 19:7 (2007),  56–66
23. CFD software project GIMM study of hydrodynamic problems by parallel computing
    
    Matem. Mod., 17:6 (2005),  58–74
24. Application of kinetically consistent finite difference schemes for turbulent supersonic jet noise prediction
    
    Matem. Mod., 13:10 (2001),  56–76
25. Kinetically consistent schemes of a higher accuracy order
    
    Matem. Mod., 13:5 (2001),  53–61
26. Difference schemes based on kinetic splitting of flux vector
    
    Matem. Mod., 12:4 (2000),  73–82
27. Application of the algebraic turbulent model to the unsteady flow simulation around a cavity
    
    Matem. Mod., 12:1 (2000),  45–56
28. Numerical simulation of supersonic jets using kinetical-consistent finite difference schemes
    
    Matem. Mod., 12:1 (2000),  25–37
29. Kinetically consistent difference algorithm for simulation of gasdynamic flows on triangular meshes
    
    Matem. Mod., 10:4 (1998),  51–60
30. Kinetically consistent difference schemes on irregular grids
    
    Matem. Mod., 9:7 (1997),  44–53
31. Kinetically consistent finite difference schemes as a model for gasdynamic flow description
    
    Matem. Mod., 8:8 (1996),  17–36
32. On an improvement of the gas flow description via kinetically-consistent difference schemes
    
    Matem. Mod., 6:7 (1994),  3–14
33. Kinetically-consistent finite difference schemes as a model for the flows of slightly rarefied gases
    
    Matem. Mod., 5:5 (1993),  61–70
34. Using kinetically-consistent difference schemes for prediction of slightly rarefied gas flows
    
    Matem. Mod., 4:11 (1992),  19–35
35. Prediction of slightly rarefied gas flows using transputer-based multiprocessor systems
    
    Matem. Mod., 4:11 (1992),  3–18
36. Direct numerical modeling of the Blasius problem
    
    Differ. Uravn., 24:7 (1988),  1107–1113