ON INTERPOLATION BY ALMOST TRIGONOMETRIC SPLINES

Sergey I. Novikov     (Krasovskii Institute of Mathematics and Mechanics, Ural Branch of Russian Academy of Sciences, Ekaterinburg, Russian Federation)

Abstract


The existence and uniqueness of an interpolating periodic spline defined on an equidistant mesh by the linear differential operator \({\cal L}_{2n+2}(D)=D^{2}(D^{2}+1^{2})(D^{2}+2^{2})\cdots (D^{2}+n^{2})\) with \(n\in\mathbb{N}\) are reproved under the final restriction on the step of the mesh. Under the same restriction, sharp estimates of the error of approximation by such interpolating periodic splines are obtained.


Keywords


Splines, Interpolation, Approximation, Linear differential operator.

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References


Korneichuk N.P. Splines in approximation theory. Moscow: Nauka, 1984. 352 p. [in Russian]

Micchelli C.A. Cardinal \(L\)-splines // Studies in spline functions and approximation theory, New York etc.: Acad. Press, 1976. P. 203–250.

Novikov S.I. Approximation of the class \(W_{\infty}^{{\cal L}_{n}}\) by interpolation periodic \(L\)-splines // Approximation of functions by polynomials and splines, Sverdlovsk: Akad. Nauk SSSR, Ural. Sc. Center, 1985. P. 118–126. [in Russian]

Novikov S.I. Generalization of the Rolle theorem // East J. Approx., 1995. Vol. 1, no. 4. P. 571–575.

Nguen Thi T.H. The operator \(D(D^2 +1^2 )\cdots (D^2+n^2)\) and trigonometric interpolation // Anal. Math., 1989. Vol. 15, no. 4. P. 291–306. [in Russian]

Nguen Thi T.H. Extremal problems for some classes of smooth periodic functions // Doctoral dissertation, 1994. Moscow: Steklov Institute of Math. 219 p. [in Russian]

Prudnikov A.P., Brychkov Yu.A., Marichev O.I. Integrals and series. Elementary functions, Moscow: Nauka, 1981. 800 p. [in Russian]

Schoenberg I.J. On Micchelli’s theory of cardinal \(L\)-splines // Studies in spline functions and approximation theory, New York etc.: Acad. Press, 1976. P. 251–276.

Shevaldin V.T. A problem of extremal interpolation // Mat. Zametki, 1981. Vol. 29, no. 4. P. 603–622. [in Russian]

Shevaldin V.T. Interpolation periodic L-splines with uniform nodes // Approximation of functions by polynomials and splines, Sverdlovsk: Akad. Nauk SSSR, Ural. Sc. Center, 1985. P. 140–147. [in Russian]

Stechkin S.B., Subbotin Yu.N. Splines in numerical mathematics. Moscow: Nauka, 1976. 248 p. [in Russian]

Tikhomirov V.M. Best methods of approximation and interpolation of differentiable functions in the space \(C[-1,1]\) // Mat. Sb., 1969. Vol. 80, no. 122. P. 290–304. [in Russian]

Zhensykbaev A.A. Approximation of differentiable periodic functions by splines on a uniform subdivision // Mat. Zametki, 1973. Vol. 13, no. 6. P. 807–816. [in Russian]

Zhang J. \(C\)-curves: an extension of cubic curves // Comput. Aided Geom. Design, 1996. Vol. 13. P. 199–217.

Roman F., Manni C., Speleers H. Spectral analysis of matrices in Galerkin methods based on generalized \(B\)-splines with high smoothness // Numer. Math., 2017. Vol. 135, no. 1. P. 169–216. DOI: 10.1007/s00211-016-0796-z

Mainar E., Peña J.M., Sánchez-Reyes J. Shape preserving alternatives to the rational Bezier model // Comput. Aided Geom. Design, 2001. Vol. 18. P. 37–60. DOI: 10.1016/S0167-8396(01)00011-5




DOI: http://dx.doi.org/10.15826/umj.2017.2.009

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