Askhabov Sultan Nazhmudinovich

Publications in Math-Net.Ru

1. Volterra type integro-differential equation with a sum-difference kernel and power nonlinearity
   
   Sib. Èlektron. Mat. Izv., 21:1 (2024),  481–494
2. Integral equation with the Toeplitz-Hankel kernel and inhomogeneity in the linear part
   
   Vestnik of Saint Petersburg University. Mathematics. Mechanics. Astronomy, 11:4 (2024),  671–683
3. Volterra integro-differential equation of arbitrary order with power nonlinearity
   
   Chebyshevskii Sb., 24:4 (2023),  85–103
4. Initial-value problem for an integro-differential equation with difference kernels and an inhomogeneity in the linear part
   
   Itogi Nauki i Tekhniki. Sovrem. Mat. Pril. Temat. Obz., 225 (2023),  3–13
5. Volterra integral equation with power nonlinearity
   
   Chebyshevskii Sb., 23:5 (2022),  6–19
6. Integro-differential equation with a sum-difference kernels and power nonlinearity
   
   Dokl. RAN. Math. Inf. Proc. Upr., 507 (2022),  10–14
7. System of inhomogeneous integral equations of convolution type with power nonlinearity
   
   Vladikavkaz. Mat. Zh., 24:1 (2022),  5–14
8. Nonlinear integro-differential equations with difference kernels
   
   Itogi Nauki i Tekhniki. Sovrem. Mat. Pril. Temat. Obz., 198 (2021),  22–32
9. Gradient method for solving nonlinear discrete and integral equations with difference kernels
   
   Itogi Nauki i Tekhniki. Sovrem. Mat. Pril. Temat. Obz., 192 (2021),  26–37
10. System of integro-differential equations of convolution type with power nonlinearity
    
    Sib. Zh. Ind. Mat., 24:3 (2021),  5–18
11. Nonlinear convolution type integral equations in complex spaces
    
    Ufimsk. Mat. Zh., 13:1 (2021),  17–30
12. A convolution type nonlinear integro-differential equation with a variable coefficient and an inhomogeneity in the linear part
    
    Vladikavkaz. Mat. Zh., 22:4 (2020),  16–27
13. On the criteria for positivity of integro-differential convolution operators
    
    Reports of AIAS, 19:1 (2019),  16–21
14. Nonlinear integral equations with potential-type kernels in the nonperiodic case
    
    Itogi Nauki i Tekhniki. Sovrem. Mat. Pril. Temat. Obz., 170 (2019),  3–14
15. Method of maximal monotonic operators in the theory of nonlinear integro-differential equations of convolution type
    
    Itogi Nauki i Tekhniki. Sovrem. Mat. Pril. Temat. Obz., 167 (2019),  3–13
16. Positivity Conditions for Operators with Difference Kernels in Reflexive Spaces
    
    Itogi Nauki i Tekhniki. Sovrem. Mat. Pril. Temat. Obz., 149 (2018),  3–13
17. Nonlinear Singular Integro-Differential Equations with an Arbitrary Parameter
    
    Mat. Zametki, 103:1 (2018),  20–26
18. Singular integro-differential equations with Hilbert kernel and monotone nonlinearity
    
    Vladikavkaz. Mat. Zh., 19:3 (2017),  11–20
19. Nonlinear integral equations with kernels of potential type on a segment
    
    CMFD, 60 (2016),  5–22
20. Periodic solutions of convolution type equations with monotone nonlinearity
    
    Ufimsk. Mat. Zh., 8:1 (2016),  22–37
21. Nonlinear Convolution-Type Equations in Lebesgue Spaces
    
    Mat. Zametki, 97:5 (2015),  643–654
22. Approximate solutions of nonlinear convolution type equations on segment
    
    Ufimsk. Mat. Zh., 5:2 (2013),  3–11
23. Nonlinear integral equations with potential type kernels on a semiaxis
    
    Vladikavkaz. Mat. Zh., 15:4 (2013),  3–11
24. Approximate solution of nonlinear discrete equations of convolution type
    
    CMFD, 45 (2012),  18–31
25. Approximate solution of nonlinear equations with weighted potential type operators
    
    Ufimsk. Mat. Zh., 3:4 (2011),  8–13
26. Nonlinear equations with weighted potential type operators in Lebesgue spaces
    
    Vestn. Samar. Gos. Tekhn. Univ., Ser. Fiz.-Mat. Nauki [J. Samara State Tech. Univ., Ser. Phys. Math. Sci.], 4(25) (2011),  160–164
27. A priori bounds of solutions of the nonlinear integral convolution type equation and their applications
    
    Mat. Zametki, 54:5 (1993),  3–12
28. Discrete equations of convolution type with monotone nonlinearity in complex spaces
    
    Dokl. Akad. Nauk, 322:6 (1992),  1015–1018
29. Nonlinear integral equations of convolution type with almost increasing kernels in cones
    
    Differ. Uravn., 27:2 (1991),  321–330
30. Integral equations of convolution type with power nonlinearity and systems of such equations
    
    Dokl. Akad. Nauk SSSR, 311:5 (1990),  1035–1039
31. Discrete equations of convolution type with monotone nonlinearity
    
    Differ. Uravn., 25:10 (1989),  1777–1784
32. Discrete equations of convolution type with power nonlinearity
    
    Dokl. Akad. Nauk SSSR, 296:3 (1987),  521–524
33. On a class of nonlinear integral equations of convolution type
    
    Differ. Uravn., 23:3 (1987),  512–514
34. Estimates of solutions of certain nonlinear equations of convolution type and singular integral equations
    
    Dokl. Akad. Nauk SSSR, 288:2 (1986),  275–278
35. A nonlinear equation of convolution type
    
    Differ. Uravn., 22:9 (1986),  1606–1609
36. Application of the method of monotone operators to some nonlinear equations of convolution type and to singular integral equations
    
    Izv. Vyssh. Uchebn. Zaved. Mat., 1981, no. 9,  64–66


37. Alexey Yakovlevich Kanel-Belov
    
    Chebyshevskii Sb., 24:4 (2023),  380–400
38. Salaudin Musaevich Umarkhadzhiev (on the occasion of his 70th birthday)
    
    Vladikavkaz. Mat. Zh., 25:1 (2023),  141–142
39. In Memory of Alexei Borisovich Shabat (08.08.1937–24.03.2020)
    
    Vladikavkaz. Mat. Zh., 22:2 (2020),  100–102
40. Alexey Borisovich Shabat (on his 80's anniversary)
    
    Vladikavkaz. Mat. Zh., 19:3 (2017),  83–85
41. Shabat Aleksei Borisovich (on his 75th birthday)
    
    Vladikavkaz. Mat. Zh., 14:2 (2012),  71–73