×

Nonlocal boundary-value problems in the cylindrical domain for the multidimensional Laplace equation. (Russian. English summary) Zbl 1437.35171

Summary: Correct statements of boundary value problems on the plane for elliptic equations by the method of analytic function theory of a complex variable. Investigating similar questions, when the number of independent variables is greater than two, problems of a fundamental nature arise. A very attractive and convenient method of singular integral equations loses its validity due to the absence of any complete theory of multidimensional singular integral equations. The author has previously studied local boundary value problems in a cylindrical domain for multidimensional elliptic equations. As far as we know, non-local boundary-value problems for these equations have not been investigated. This paper uses the method proposed in the author’s earlier works, shows unique solvabilities, and gives explicit forms of classical solutions of nonlocal boundary-value problems in the cylindrical domain for the multidimensional Laplace equation, which are generalizations of the mixed problem, the Dirichlet and Poincare problems. A criterion for uniqueness is also obtained for regular solutions of these problems is also obtained.

MSC:

35J05 Laplace operator, Helmholtz equation (reduced wave equation), Poisson equation
35J25 Boundary value problems for second-order elliptic equations
PDFBibTeX XMLCite
Full Text: DOI MNR

References:

[1] Aldashev S. A., “The correctness of the Dirichlet problem in cylindrical domain for the multidimensional Laplace equation”, Izv. Saratov Univ. (N. S.), Ser. Math. Mech. Inform., 12:3 (2012), 3-7 (in Russian) · Zbl 1301.35007
[2] Aldashev S. A., “Correctness of Poincare”s problem in a cylindrical region for Laplace’s multi-measured equation”, News of the National Academy of Sciences of the Republic of Kazakhstan. Physical-mathematical Series, 2014, no. 3 (295), 62-67 (in Russian)
[3] Aldashev S. A., “The correctness of the Dirichlet problem in cylindrical domain for a class of multidimensional elliptic equations”, Vestn. Novosib. Gos. Univ., Ser. Mat. Mekh. Inform., 12:1 (2012), 7-13 (in Russian) · Zbl 1249.35079
[4] Aldashev S. A., “Well-Posedness of Poincare Problem in the Cylindrical Domain for a Class of Multi-Dimensional Elliptic Equations”, Vestnik of Samara University. Natural Science Series, 2014, no. 10 (121), 17-25 (in Russian) · Zbl 1334.35031
[5] Aldashev S. A., “The correctness of the local boundary value problem in cylindrical domain for the multidimensional Laplace equation”, Izv. Saratov Univ. (N. S.), Ser. Math. Mech. Inform., 15:4 (2015), 365-371 (in Russian) · Zbl 1352.35033 · doi:18500/1816-9791-2015-15-4-365-371
[6] Aldashev S. A., “The correctness of the local boundary value problem in cylindrical domain for a class of multidimensional elliptic equations”, Vestnik of Samara University. Natural Science Series, 12(123):1-2 (2016), 7-17 (in Russian) · Zbl 1391.35114
[7] Mikhlin S. G., Multidimensional singular integrals and Integral equations, Fizmatgiz, M., 1962, 254 pp. (in Russian)
[8] Kamke E., Handbook of Ordinary Differential Equations, Nauka, M., 1965, 703 pp. (in Russian)
[9] Bateman G., Erdei A., Higher transcendental functions, v. 2, Nauka, M., 1974, 295 pp. (in Russian)
[10] Tikhonov A. N., Samarskii A. A., Equations of mathematical physics, Nauka, M., 1966, 724 pp. (in Russian) · Zbl 0044.09302
This reference list is based on information provided by the publisher or from digital mathematics libraries. Its items are heuristically matched to zbMATH identifiers and may contain data conversion errors. In some cases that data have been complemented/enhanced by data from zbMATH Open. This attempts to reflect the references listed in the original paper as accurately as possible without claiming completeness or a perfect matching.