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Publications in Math-Net.Ru
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Fejér-Type Iterative Processes in the Constrained Quadratic Minimization Problem
Trudy Inst. Mat. i Mekh. UrO RAN, 29:3 (2023), 26–41
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Erratum to: Several Articles in Doklady Mathematics
Dokl. RAN. Math. Inf. Proc. Upr., 506 (2022), 404–405
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Solving nonlinear inverse problems based on the regularized modified Gauss–Newton method
Dokl. RAN. Math. Inf. Proc. Upr., 504 (2022), 47–50
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Two-stage method for solving systems of nonlinear equations and its applications to the inverse atmospheric sounding problem
Dokl. RAN. Math. Inf. Proc. Upr., 494 (2020), 17–20
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Iterative Fejér processes in ill-posed problems
Zh. Vychisl. Mat. Mat. Fiz., 60:6 (2020), 963–974
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Regularized Newton type method for retrieval of heavy water in atmosphere by IR–spectra of the solar light transmission
Eurasian Journal of Mathematical and Computer Applications, 7:2 (2019), 79–88
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Analysis of a Regularization Algorithm for a Linear Operator Equation Containing a Discontinuous Component of the Solution
Trudy Inst. Mat. i Mekh. UrO RAN, 25:3 (2019), 34–44
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Iterative processes for ill-posed problems with a monotone operator
Mat. Tr., 21:2 (2018), 117–135
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Modification of the tikhonov method under separate reconstruction of components of solution with various properties
Eurasian Journal of Mathematical and Computer Applications, 5:2 (2017), 66–79
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A two-stage method of construction of regularizing algorithms for nonlinear ill-posed problems
Trudy Inst. Mat. i Mekh. UrO RAN, 23:1 (2017), 57–74
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Methods for solving nonlinear ill-posed problems based on the Tikhonov-Lavrentiev regularization and iterative approximation
Eurasian Journal of Mathematical and Computer Applications, 4:4 (2016), 60–73
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Solution of the deconvolution problem in the general statement
Trudy Inst. Mat. i Mekh. UrO RAN, 22:2 (2016), 79–90
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Separate reconstruction of solution components with singularities of various types for linear operator equations of the first kind
Trudy Inst. Mat. i Mekh. UrO RAN, 20:2 (2014), 63–73
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Modified Newton-type processes generating Fejér approximations of regularized solutions to nonlinear equations
Trudy Inst. Mat. i Mekh. UrO RAN, 19:2 (2013), 85–97
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Iterative Newton Type Algorithms and Its Applications to Inverse Gravimetry Problem
Vestnik YuUrGU. Ser. Mat. Model. Progr., 6:3 (2013), 26–37
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The Levenberg–Marquardt method for approximation of solutions of irregular operator equations
Avtomat. i Telemekh., 2012, no. 3, 28–38
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Levenberg–Marquardt method and its modified versions for solving nonlinear equations with application to the inverse gravimetry problem
Trudy Inst. Mat. i Mekh. UrO RAN, 17:2 (2011), 53–61
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Iterative processes of the Fejér type in ill-posed problems with a prori information
Izv. Vyssh. Uchebn. Zaved. Mat., 2009, no. 2, 3–24
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Methods for inverse magnitometry problem solving
Sib. Èlektron. Mat. Izv., 5 (2008), 620–631
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The inverse problem of atmosphere thermal sounding
Sib. Èlektron. Mat. Izv., 5 (2008), 518–523
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Concluding scientific report for the project of Siberian Division of RAS: “A development of theory and computational technology for solving inverse and extremal problems with an application to mathematical physics and gravity-magneto-prospecting”
Sib. Èlektron. Mat. Izv., 5 (2008), 427–439
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On regular methods for solving the inverse gravity problems on massively parallel computing systems
Num. Meth. Prog., 8:1 (2007), 103–112
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Approximation of nonsmooth solutions of linear ill-posed problems
Trudy Inst. Mat. i Mekh. UrO RAN, 12:1 (2006), 64–77
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Two-stage approximation of nonsmooth solutions and restoration of noised images
Avtomat. i Telemekh., 2004, no. 2, 126–135
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Direct and inverse problems of oblique radiosounding of ionosphere with waveguids
Matem. Mod., 16:3 (2004), 22–32
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Solution of gravity and magnetic three-dimensional inverse problems for three-layers medium
Matem. Mod., 15:2 (2003), 69–76
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Algorithms for solving direct and inverse problems of oblique radio-sounding ionosphere
Matem. Mod., 14:11 (2002), 23–32
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Regularization and iterative approximation for linear ill-posed problems in the space of functions of bounded variation
Trudy Inst. Mat. i Mekh. UrO RAN, 8:1 (2002), 189–202
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On an algorithm for solving the Fredholm–Stieltjes equation
Izv. Vyssh. Uchebn. Zaved. Mat., 2001, no. 4, 3–10
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Solving nonlinear gravity inverse problem by gradient type methods
Matem. Mod., 11:10 (1999), 86–91
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Monotone iterative processes for operator equations in partially
ordered spaces
Dokl. Akad. Nauk, 349:1 (1996), 7–9
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Iterative regularization of monotone operator equations of the
first kind in partially ordered $B$-spaces
Dokl. Akad. Nauk, 341:2 (1995), 151–154
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Iterative regularization methods for ill-posed problems
Izv. Vyssh. Uchebn. Zaved. Mat., 1995, no. 11, 69–84
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Iterative approximation of the solution in a finite moment
problem
Dokl. Akad. Nauk SSSR, 318:5 (1991), 1042–1045
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Iterative methods for solving ill-posed problems with a priori information in Hilbert spaces
Zh. Vychisl. Mat. Mat. Fiz., 28:7 (1988), 971–980
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Some methods of approximate solution of differential and integral equations
Izv. Vyssh. Uchebn. Zaved. Mat., 1983, no. 7, 13–27
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Stable discretization of extremal problems and its applications in mathematical programming
Mat. Zametki, 31:2 (1982), 269–280
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Discrete approximation and stability in extremal problems
Zh. Vychisl. Mat. Mat. Fiz., 22:4 (1982), 824–839
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A general scheme for discretization of regularizing algorithms in Banach spaces
Dokl. Akad. Nauk SSSR, 258:2 (1981), 271–275
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Discrete convergence and finite-dimensional approximation of regularizing algorithms
Zh. Vychisl. Mat. Mat. Fiz., 19:1 (1979), 11–21
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Stable approximation of infinite-dimensional problems of linear and convex programming
Izv. Vyssh. Uchebn. Zaved. Mat., 1978, no. 11, 23–33
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Optimality with respect to order of the regularization method for nonlinear operator equations
Zh. Vychisl. Mat. Mat. Fiz., 17:4 (1977), 847–858
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The stability of projection methods in the solution of ill-posed problems
Zh. Vychisl. Mat. Mat. Fiz., 15:1 (1975), 19–29
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Necessary and sufficient conditions for convergence of projection methods for linear unstable problems
Dokl. Akad. Nauk SSSR, 215:5 (1974), 1032–1034
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The stable evaluation of a derivative in space $C(-\infty,\infty)$
Zh. Vychisl. Mat. Mat. Fiz., 13:6 (1973), 1383–1389
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On the problem of computing the values of an unbounded operator in $B$-spaces
Izv. Vyssh. Uchebn. Zaved. Mat., 1972, no. 5, 22–28
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The $\beta $-convergence of the projection method for nonlinear operator equations
Zh. Vychisl. Mat. Mat. Fiz., 12:2 (1972), 492–497
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A certain projection method of solution of ill-posed problems
Izv. Vyssh. Uchebn. Zaved. Mat., 1971, no. 11, 28–32
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Relationship of several variational methods for the approximate solution of ill-posed problems
Mat. Zametki, 7:3 (1970), 265–272
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Regularization of nonlinear partial differential equations
Differ. Uravn., 4:12 (1968), 2268–2274
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Yurii Nikolaevich Subbotin (A Tribute to His Memory)
Trudy Inst. Mat. i Mekh. UrO RAN, 28:4 (2022), 9–16
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Leonid Aleksandrovich Aksent'ev
Izv. Vyssh. Uchebn. Zaved. Mat., 2021, no. 3, 98–100
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Ivan Ivanovich Eremin
Trudy Inst. Mat. i Mekh. UrO RAN, 20:2 (2014), 5–12
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International conference “Algorithmic analysis of unstable problems (AAUP-2011)”
Trudy Inst. Mat. i Mekh. UrO RAN, 18:1 (2012), 329–333
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To the 75th anniversary of academician of Russian Academy of Sciences Yu. S. Osipov
Trudy Inst. Mat. i Mekh. UrO RAN, 17:2 (2011), 5–6
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On the history of the Ural Conference on Ill-Posed Problems
Trudy Inst. Mat. i Mekh. UrO RAN, 15:3 (2009), 279–281
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On the collaboration of Siberian and Ural mathematicians
Sib. Èlektron. Mat. Izv., 4 (2007), 22–27
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Academician M. M. Lavrent'ev (on the occasion of his 75th birthday)
Sib. Zh. Ind. Mat., 10:3 (2007), 3–12
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Valentin Konstantinovich Ivanov (obituary)
Uspekhi Mat. Nauk, 48:5(293) (1993), 147–152
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Valentin Konstantinovich Ivanov (on the occasion of his eightieth birthday)
Izv. Vyssh. Uchebn. Zaved. Mat., 1988, no. 10, 3–4
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