Abrashina-Zhadaeva Natal'ya Grigor'evna

Publications in Math-Net.Ru

1. Approximate factorization method for two-dimensional equations in partial fractional derivatives on finite domain
   
   Kazan. Gos. Univ. Uchen. Zap. Ser. Fiz.-Mat. Nauki, 151:3 (2009),  63–73
2. Multicomponent vector decomposition schemes for the solution of multidimensional problems of mathematical physics
   
   Differ. Uravn., 42:7 (2006),  883–894
3. On the Numerical Error of Vector-Additive Iterative Methods
   
   Differ. Uravn., 41:7 (2005),  990–993
4. On an additive method for nonstationary Navier–Stokes equations
   
   Izv. Vyssh. Uchebn. Zaved. Mat., 2005, no. 1,  3–9
5. On additive iterative methods and estimates for their rate of convergence
   
   Izv. Vyssh. Uchebn. Zaved. Mat., 2003, no. 1,  3–11
6. An Economical Method for Multidimensional Motion and Transport Equations
   
   Differ. Uravn., 38:9 (2002),  1257–1262
7. Economical Additive Finite-Difference Schemes for Miltidimensional Nonlinear Nonstationary Problems
   
   Differ. Uravn., 38:7 (2002),  907–917
8. On a Class of Additive Iterative Methods
   
   Differ. Uravn., 37:12 (2001),  1664–1673
9. On the Convergence Rate of Additive Iterative Methods
   
   Differ. Uravn., 37:7 (2001),  867–879
10. The convergence rate of economical iterative methods for stationary problems of mathematical physics
    
    Differ. Uravn., 36:9 (2000),  1220–1229
11. Efficient iterative schemes for realizing the finite element method for stationary boundary value problems in mathematical physics
    
    Izv. Vyssh. Uchebn. Zaved. Mat., 2000, no. 11,  3–11
12. Subcritical systems with arbitrary released energy
    
    Matem. Mod., 12:2 (2000),  35–44
13. Additive iterative methods for solving stationary problems for the Navier–Stokes equations
    
    Differ. Uravn., 35:11 (1999),  1543–1552
14. On a composition method for constructing iterative algorithms for solving stationary problems in mathematical physics
    
    Differ. Uravn., 35:7 (1999),  948–957
15. The domain decomposition method for solving grid parabolic problems
    
    Differ. Uravn., 35:2 (1999),  225–231
16. On a class of difference methods for solving Navier–Stokes equations
    
    Izv. Vyssh. Uchebn. Zaved. Mat., 1999, no. 5,  3–11
17. A multicomponent alternating direction method for solving stationary problems of mathematical physics. II
    
    Differ. Uravn., 33:9 (1997),  1211–1219
18. A multicomponent variant of the method of variable directions for evolution problems. II
    
    Differ. Uravn., 33:7 (1997),  998–1000
19. A multicomponent alternating direction method for solving stationary problems of mathematical physics. I
    
    Differ. Uravn., 32:9 (1996),  1212–1221
20. On a domain decomposition method in nonstationary problems of mathematical physics
    
    Differ. Uravn., 31:7 (1995),  1217–1221
21. Efficient methods for solving first-order hyperbolic systems
    
    Differ. Uravn., 30:7 (1994),  1187–1193
22. A multicomponent variant of the method of variable directions for evolution problems. I
    
    Differ. Uravn., 28:7 (1992),  1218–1230
23. Convergence of the grid method in the solution of nonlinear nonstationary problems
    
    Differ. Uravn., 16:9 (1980),  1710–1713
24. Difference schemes for nonlinear Stefan problems
    
    Differ. Uravn., 12:9 (1976),  1712–1714