Medvedev Alexey Elizarovich

Publications in Math-Net.Ru

1. Modeling of aortic deformation in aneurysm and wall dissection
   
   Chelyab. Fiz.-Mat. Zh., 9:2 (2024),  255–260
2. Three-dimensional simulation of heat and moisture transfer in the human bronchial tree
   
   J. Sib. Fed. Univ. Math. Phys., 17:1 (2024),  136–145
3. Mathematical analysis of aortic deformation in aneurysm and wall dissection
   
   Mat. Biolog. Bioinform., 18:Suppl. (2023),  94–106
4. Mathematical analysis of aortic deformation in aneurysm and wall dissection
   
   Mat. Biolog. Bioinform., 18:2 (2023),  464–478
5. Physicomathematical modeling of human breathing in situations of various pulmonary diseases
   
   Prikl. Mekh. Tekh. Fiz., 64:6 (2023),  114–118
6. Construction of complex three-dimensional structures of the aorta of a particular patient using finite analytical formulas
   
   Mat. Biolog. Bioinform., 17:Suppl. (2022),  30–41
7. Simulation of air motion in human lungs during breathing. Dynamics of liquid droplet precipitation in the case of medicine drug aerosols
   
   Mat. Biolog. Bioinform., 17:Suppl. (2022),  14–29
8. Construction of complex three-dimensional structures of the aorta of a particular patient using finite analytical formulas
   
   Mat. Biolog. Bioinform., 17:2 (2022),  312–324
9. Simulation of air motion in human lungs during breathing. Dynamics of liquid droplet precipitation in the case of medicine drug aerosols
   
   Mat. Biolog. Bioinform., 16:2 (2021),  422–438
10. Method of constructing an asymmetric human bronchial tree in normal and pathological cases
    
    Mat. Biolog. Bioinform., 15:Suppl. (2020),  21–31
11. Method of constructing an asymmetric human bronchial tree in normal and pathological cases
    
    Mat. Biolog. Bioinform., 15:2 (2020),  148–157
12. Three-dimensional model of the human bronchial tree – modeling of the air flow in normal and pathological cases
    
    Prikl. Mekh. Tekh. Fiz., 61:1 (2020),  3–16
13. Analytical design of the human bronchial tree for healthy patients and patients with obstructive pulmonary diseases
    
    Mat. Biolog. Bioinform., 14:Suppl. (2019),  62–75
14. Analytical design of the human bronchial tree for healthy patients and patients with obstructive pulmonary diseases
    
    Mat. Biolog. Bioinform., 14:2 (2019),  635–648
15. Approximate modeling of the flow structure in a $\lambda$-shaped pseudoshock
    
    Prikl. Mekh. Tekh. Fiz., 55:6 (2014),  43–59
16. Unsteady motion of a viscous incompressible fluid in a tube with a deformable wall
    
    Prikl. Mekh. Tekh. Fiz., 54:4 (2013),  45–54
17. A two-phase model of blood flow in large and small blood vessels
    
    Mat. Biolog. Bioinform., 6:2 (2011),  228–249
18. Modeling of the differential rotation effect in complex loading of granular media
    
    Prikl. Mekh. Tekh. Fiz., 50:4 (2009),  139–149
19. Three-dimensional motion of a viscous incompressible fluid in a narrow tube
    
    Prikl. Mekh. Tekh. Fiz., 50:4 (2009),  28–32
20. Computer system of modules integration for automatic construction and numerical analysis of molecular genetic systems
    
    Sib. Èlektron. Mat. Izv., 6 (2009),  440–456
21. Rational structure of blood vessels
    
    Prikl. Mekh. Tekh. Fiz., 47:3 (2006),  24–30
22. Reflection of an oblique shock wave in a reacting gas with a finite relaxation–zone length
    
    Prikl. Mekh. Tekh. Fiz., 42:2 (2001),  33–41
23. Steady states of the surface of a nonadiabatic flame near the limits
    
    Fizika Goreniya i Vzryva, 35:4 (1999),  3–11
24. Approximate analytical calculation of the mach configuration of steady shock waves in a plane constricting channel
    
    Prikl. Mekh. Tekh. Fiz., 39:3 (1998),  52–58
25. Detonation in a relaxing gas with two heat-producing reactions
    
    Fizika Goreniya i Vzryva, 28:3 (1992),  89–93
26. Investigation of the adiabat of heterogeneous two-phase detonation
    
    Fizika Goreniya i Vzryva, 23:2 (1987),  115–121
27. Description of ignition and combustion of gas mixtures with solid particles by methods of the mechanics of continuous media
    
    Fizika Goreniya i Vzryva, 20:2 (1984),  3–9
28. Mathematical modeling of metal particle ignition in the high-temperature flow behind a shock
    
    Fizika Goreniya i Vzryva, 18:3 (1982),  5–9