Zorkal'tsev Valerii Ivanovich

Publications in Math-Net.Ru

1. Comparative analysis of algorithms for estimating fish population dynamics
   
   Diskretn. Anal. Issled. Oper., 31:2 (2024),  80–95
2. Multiplicative model the allocation of components of the time series
   
   Sib. Zh. Vychisl. Mat., 25:2 (2022),  111–127
3. Chebyshev approximations do not need the Haar condition
   
   Itogi Nauki i Tekhniki. Sovrem. Mat. Pril. Temat. Obz., 196 (2021),  28–35
4. Mitigating uncertainty in developing scientific applications in integrated environment
   
   Proceedings of ISP RAS, 33:1 (2021),  151–172
5. Chebyshev approximations by least squares method
   
   Bulletin of Irkutsk State University. Series Mathematics, 33 (2020),  3–19
6. Chebyshev projections to a linear manifold
   
   Trudy Inst. Mat. i Mekh. UrO RAN, 26:3 (2020),  44–55
7. Results of the analysis of requirements for methods for allocating time series components
   
   UBS, 88 (2020),  26–40
8. Multiplicative model of trend detection and seasonal fluctuations: application to the dynamics of prices for agricultural products
   
   UBS, 86 (2020),  98–115
9. Convergence of Hölder projections to chebyshev projections
   
   Zh. Vychisl. Mat. Mat. Fiz., 60:11 (2020),  1867–1880
10. An algorithm for determining optimal and suboptimal trajectories of the development of a system
    
    Sib. Zh. Ind. Mat., 22:1 (2019),  34–40
11. Chebyshev and euclidean projections of point on linear manifold
    
    UBS, 80 (2019),  6–19
12. Models and methods for reliability analysis of the energy supply of remote settlements
    
    UBS, 78 (2019),  221–234
13. Interior point method: history and prospects
    
    Zh. Vychisl. Mat. Mat. Fiz., 59:10 (2019),  1649–1665
14. Formation of the development options for energy systems by combinatorial modeling methods
    
    Sib. Zh. Ind. Mat., 21:3 (2018),  37–49
15. Interior point algorithms in linear optimization
    
    Sib. Zh. Ind. Mat., 21:1 (2018),  11–20
16. Octahedral projections of a point onto a polyhedron
    
    Zh. Vychisl. Mat. Mat. Fiz., 58:5 (2018),  843–851
17. Date selection of the beginning of the economic year on the minimization criteria of the seasonal oscillations amplitude
    
    Bulletin of Irkutsk State University. Series Mathematics, 22 (2017),  50–62
18. A study into unsteady oligopolistic markets
    
    Sib. Zh. Ind. Mat., 20:1 (2017),  11–20
19. The search for admissible solutions by the interior point algorithms
    
    Sib. Zh. Vychisl. Mat., 19:3 (2016),  249–265
20. Of entering into the feasible solutions region the interior point method
    
    UBS, 59 (2016),  23–44
21. Oligopolistic interacting markets
    
    Sib. Zh. Vychisl. Mat., 18:4 (2015),  361–368
22. The weight coefficients in the weighted least squares method
    
    Sib. Zh. Vychisl. Mat., 18:3 (2015),  275–288
23. Interacting oligopolistic and oligopsonistic Cournot markets
    
    UBS, 56 (2015),  95–107
24. Theoretical justification of interior point algorithms for solving optimization problems with nonlinear constraints
    
    Sib. Zh. Vychisl. Mat., 16:1 (2013),  27–38
25. Computational experiments with variants of interior-point algorithms for nonlinear flow distribution problems
    
    UBS, 46 (2013),  68–87
26. Проекции точки на полиэдр
    
    Zh. Vychisl. Mat. Mat. Fiz., 53:1 (2013),  4–19
27. Models for estimating the power deficit in electric power grid
    
    Sib. Zh. Ind. Mat., 15:1 (2012),  34–43
28. Octahedral and Euclidean projections of a point to a linear manifold
    
    Trudy Inst. Mat. i Mekh. UrO RAN, 18:3 (2012),  106–118
29. Linear inequalities system’s solutions least distant from origin of coordinates
    
    Bulletin of Irkutsk State University. Series Mathematics, 4:2 (2011),  102–113
30. Dual interior point algorithms
    
    Izv. Vyssh. Uchebn. Zaved. Mat., 2011, no. 4,  33–53
31. The model of power shortage evaluation of electrical power system
    
    Bulletin of Irkutsk State University. Series Mathematics, 3:3 (2010),  80–92
32. Application of the duality theory in modeling hydraulic systems with flow regulators
    
    Izv. Vyssh. Uchebn. Zaved. Mat., 2010, no. 9,  76–81
33. The flow distribution problem in a nonclassical statement
    
    Sib. Zh. Ind. Mat., 13:4 (2010),  15–24
34. A model of power shortage evaluation of electric power systems with quadratic losses of power in power lines
    
    Sib. Zh. Vychisl. Mat., 13:3 (2010),  285–295
35. Model of power shortage optimization in electric power system
    
    UBS, 30.1 (2010),  300–318
36. Model of hydraulic circuit with flow regulators
    
    UBS, 30.1 (2010),  286–299
37. On a class of interior point algorithms
    
    Zh. Vychisl. Mat. Mat. Fiz., 49:12 (2009),  2114–2130
38. Nash equilibrium in transport model with quadratic costs
    
    Diskretn. Anal. Issled. Oper., 15:3 (2008),  31–42
39. Symmetric duality in optimization and its applications
    
    Izv. Vyssh. Uchebn. Zaved. Mat., 2006, no. 12,  55–64
40. Solution of systems of two-sided linear inequalities by interior-point algorithms using the example of a model of the operating conditions of electrical power systems
    
    Diskretn. Anal. Issled. Oper., Ser. 2, 11:1 (2004),  62–79
41. New variants of dual interior point algorithms for systems of linear inequalities
    
    Zh. Vychisl. Mat. Mat. Fiz., 44:7 (2004),  1234–1243
42. The use of the interior point method for the realization of a model for the estimation of the power deficit of electrical power systems
    
    Diskretn. Anal. Issled. Oper., Ser. 2, 8:2 (2001),  31–41
43. Oblique path algorithms for solving linear programming problems
    
    Diskretn. Anal. Issled. Oper., Ser. 2, 8:2 (2001),  17–26
44. Finding admissible regimes of electric power systems by means of inner-point algorithms
    
    Sib. Zh. Ind. Mat., 3:1 (2000),  57–65
45. Optimization algorithms in the cone of central path
    
    Zh. Vychisl. Mat. Mat. Fiz., 40:2 (2000),  318–327
46. New algorithms for optimization in the cone of the central path
    
    Diskretn. Anal. Issled. Oper., Ser. 2, 6:1 (1999),  33–42
47. Substantiation of interior point algorithms
    
    Zh. Vychisl. Mat. Mat. Fiz., 39:2 (1999),  208–221
48. The points of a linear manifold nearest the origin of coordinates
    
    Zh. Vychisl. Mat. Mat. Fiz., 35:5 (1995),  801–810
49. A self-adjoint algorithm for solving linear programming problems
    
    Izv. Vyssh. Uchebn. Zaved. Mat., 1994, no. 12,  42–49
50. Algorithms of projective optimization which use the multipliers of previous iterations
    
    Zh. Vychisl. Mat. Mat. Fiz., 34:7 (1994),  1095–1103


51. In Memory of Professor Valerian Pavlovich Bulatov
    
    Zh. Vychisl. Mat. Mat. Fiz., 51:5 (2011),  958–960