Geodesic
Fourier method related with orthogonal splines in parabolic initial boundary value problem for domain with curvilinear boundary
Ufa mathematical journal, Tome 14 (2022) no. 2, pp. 56-66

Voir la notice de l'article provenant de la source Math-Net.Ru

The Fourier method allows one to find solutions to boundary value problems and initial boundary value problems for partial differential equations admitting the separation of variables. The application of the method for problems of many types faces significant difficulties. One of the directions on extending the domain of applicability of the Fourier method is to overcome the mathematical problems related with this method, for instance, ones related with a nature of boundary conditions. Another direction concerns the usage of special functions for the domains of classical forms defined by coordinate lines and surfaces of orthogonal curvilinear coordinates. But in the general case of domains with curvilinear boundaries such approach is ineffective. The directions of developing the Fourier method for solving problems in domains with curvilinear boundary are related also, first, with developing and applying variation grid and projection grid method and second, with a modification of the Fourier method itself. The present paper belongs to the second direction and is aimed on extending the applicability domain of the Fourier method, which is determined by constructing a sequence of finite generalized Fourier series related with orthogonal splines and giving analytic solutions to a parabolic initial boundary value problem in the domain with a curved boundary. For such problem, we propose and study an algorithm of the Fourier method related with the application of orthogonal splines. A sequence of finite generalized Fourier series generated by this algorithm converges to the exact solution given by an infinite Fourier series at each time moment. While increasing the number of the nodes in the grid in the considered domain with a curvilinear boundary, the structure of the finite Fourier series approaches the structure of an infinite Fourier series being an exact solution of initial boundary value problem. The method provides approximate analytic solutions with an arbitrary accuracy in the form of orthogonal series, which are generalized Fourier series, and this gives new opportunities of the classical Fourier method.
Keywords: parabolic initial boundary value problem, curved boundary, separation of variables, generalized Fourier series, orthogonal splines. 
V. L. Leontiev. Fourier method related with orthogonal splines in parabolic initial boundary value problem for domain with curvilinear boundary. Ufa mathematical journal, Tome 14 (2022) no. 2, pp. 56-66. http://geodesic.mathdoc.fr/item/UFA_2022_14_2_a3/
@article{UFA_2022_14_2_a3,
     author = {V. L. Leontiev},
     title = {Fourier method related with orthogonal splines in parabolic initial boundary value problem for domain with curvilinear boundary},
     journal = {Ufa mathematical journal},
     pages = {56--66},
     year = {2022},
     volume = {14},
     number = {2},
     language = {en},
     url = {http://geodesic.mathdoc.fr/item/UFA_2022_14_2_a3/}
}
TY  - JOUR
AU  - V. L. Leontiev
TI  - Fourier method related with orthogonal splines in parabolic initial boundary value problem for domain with curvilinear boundary
JO  - Ufa mathematical journal
PY  - 2022
SP  - 56
EP  - 66
VL  - 14
IS  - 2
UR  - http://geodesic.mathdoc.fr/item/UFA_2022_14_2_a3/
LA  - en
ID  - UFA_2022_14_2_a3
ER  - 
%0 Journal Article
%A V. L. Leontiev
%T Fourier method related with orthogonal splines in parabolic initial boundary value problem for domain with curvilinear boundary
%J Ufa mathematical journal
%D 2022
%P 56-66
%V 14
%N 2
%U http://geodesic.mathdoc.fr/item/UFA_2022_14_2_a3/
%G en
%F UFA_2022_14_2_a3

[1] V.L. Leontiev, Orthogonal splines and special functions in methods of numerical mechanics and mathematics, Polytech Press, St.-Petersburg, 2021 (in Russian)

[2] E.A. Gasymov, A.O. Guseinova, U.N. Gasanova, “Application of generalized separation of variables to solving mixed problems with irregular boundary conditions”, Comp. Math. Math. Phys., 56:7 (2016), 1305–1309

[3] I.A. Savichev, A.D. Chernyshov, “Application of the angular superposition method to the contact problem on the compression of an elastic cylinder”, Mech. Solids, 44:3 (2009), 463–472

[4] A.P. Khromov, M.Sh. Burlutskaya, “Classical solution by the Fourier method of mixed problems with minimum requirements on the initial data”, Izv. Saratov. Univ. Nov. Ser. Ser. Matem. Mekh. Inform., 14:2 (2014), 171–198 (in Russian)

[5] V.L. Kolmogorov, V.P. Fedotova, L.F. Spevak, N.A. Babailov, V.B. Trukhin, “Solving of nonstationary temperature and thermomechanical problems by separation of variables in variational setting”, Vestn. Samar. Gos. Tekhn. Univ., Ser. Fiz.-Mat. Nauki, 42 (2006), 72–75

[6] Yu.I. Malov, L.K. Martinson, K.B. Pavlov, “Solution by separation of the variables of some mixed boundary value problems in the hydrodynamics of conducting media”, Comp. Math. Math. Phys., 12:3 (1972), 71–86

[7] M.Sh. Israilov, “Diffraction of acoustic and elastic waves on a half-plane for boundary conditions of various types”, Mech. Solids, 48:3 (2013), 337–347

[8] V. Anders, Fourier analysis and its applications, Springer-Verlag, New York–Berlin–Heidelberg, 2003, 269 pp.

[9] A.B. Usov, “Finite-difference method for the Navier-Stokes equations in a variable domain with curved boundaries”, Comp. Math. Math. Phys., 48:3 (2008), 464–476

[10] P.A. Krutitskii, “The first initial-boundary value problem for the gravity-inertia wave equation in a multiply connected domain”, Comp. Math. Math. Phys., 37:1 (1997), 113–123

[11] M.I. Chebakov, “Certain dynamic and static contact problems of the theory of elasticity for a circular cylinder of finite size”, J. Appl. Math. Mech., 44:5 (1980), 651–658

[12] G. Strang, G.J. Fix, An analysis of the finite element method, Prentice-Hall, Inc., Englewood Cliffs, N.J., 1973

[13] V.L. Leontiev, “Fourier Method in Initial Boundary Value Problems for Regions with Curvilinear Boundaries”, Mathematics and Statistics, 9:1 (2021), 24–30

[14] S.G. Mikhlin, Mathematical physics, an advanced course, North-Holland Publ. Co., London, 1970

[15] V.Ya. Arsenin, Methods of mathematical physics and special functions, Nauka, M., 1974 (in Russian)

[16] A.A. Samarskii, E.S. Nikolaev, Metody resheniya setochnykh uravneniya, Glavnaya redaktsiya fiziko-matematicheskoi literatury izd-va «Nauka», M., 1978, 592 pp.; A.A. Samarskij, E.S. Nikolaev, Numerical methods for grid equations, v. I, Direct methods; v. II, Iterative methods, Birkhäuser Verlag, Basel, 1989