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Zawartość
Pełne teksty:
Warianty tytułu
Abstrakty
CONTENTS
Introduction...........................................................................................................5
I. Canonical complete Chebyshev systems
1. Canonical complete Chebyshev systems.......................................................7
2. Interpolation by generalized polynomials and divided differences................12
3. The Markov inequality for generalized polynomials......................................16
II. Chebyshevian splines
1. Basic properties...........................................................................................18
2. B-splines......................................................................................................21
3. The Marsden identity...................................................................................28
4. De Boor's inequalities..................................................................................32
5. A recurrence relation for B-splines...............................................................37
6. Bounds on zeros..........................................................................................41
III. Spline operators
1. Orthogonal spline projections .....................................................................46
2. Biorthogonal systems..................................................................................49
3. Equivalence of spline bases .......................................................................57
4. Positive spline operators and orthogonal splines .......................................60
IV. Generalized moduli of smoothness and approximation by splines
1. Generalized moduli of smoothness .............................................................64
2. Generalization of the Whitney Theorem.......................................................70
3. Best approximation by splines......................................................................72
4. The Bernstein type inequality for splines ....................................................77
V. Applications to approximation of analytic functions
1. Approximation by analytic splines................................................................78
2. Biorthogonal systems in the complex space A(D)........................................83
3. Systems conjugate to biorthogonal spline systems......................................86
References.........................................................................................................94
List of symbols....................................................................................................98
Słowa kluczowe
Tematy
Miejsce publikacji
Warszawa
Copyright
Seria
Rozprawy Matematyczne
tom/nr w serii:
305
Liczba stron
98
Liczba rozdzia³ów
Opis fizyczny
Dissertationes Mathematicae, Tom CCCV
Daty
wydano
1990
otrzymano
1989-12-06
Twórcy
autor
- Institute of Mathematics, Academy of Mining and Metallurgy, Al. Mickiewicza 30, 30-059 Kraków, Poland
Bibliografia
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- [52] K. Scherer and L. L. Schumaker, A dual basis for L-splines and applications, ibid. 29 (1980), 151-169.
- [53] I. J. Schoenberg, On trigonometric spline interpolation, J. Math. Mech. 13 (1964), 795-825.
- [54] S. Schonefeld, Schauder bases in the Banach space C²(T²), Trans. Amer. Math. Soc. 165 (1972), 300-318.
- [55] L. L. Schumaker, On Tchebycheffian spline functions, J. Approx. Theory 18 (1976), 278-303.
- [56] L. L. Schumaker, Towards a constructive theory of generalized spline functions, in: Spline Functions, K. Böhmer, G. Meinardus and W. Schemp (eds.), Lecture Notes in Math. 501, Springer, New York 1976, 265-331.
- [57] L. L. Schumaker, Spline Functions: Basic Theory, Wiley, New York 1981.
- [58] B. Sendov, A new proof of the H. Whitney's Theorem, C. R. Acad. Bulg. Sci. 35 (1982), 609-611.
- [59] L. L. Schumaker, The constants of H. Whitney are bounded, ibid. 38 (1985), 1299-1302.
- [60] E. M. Stein, Singular Integrals and Differentiability Properties of Functions, Princeton Univ. Press, 1970.
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- [62] P. M. Tamrazov, Smoothness and Polynomial Approximation, Naukova Dumka, Kiev 1975 (in Russian).
- [63] A. F. Timan, Theory of Approximation of Functions of a Real Variable, Fizmatgiz, Moscow 1960 (in Russian).
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- [65] Z. Wronicz, On the approximation and interpolation by multiple splines, Zeszyty Nauk. Uniw. Jagielloń. Prace Mat. 17 (1975), 147-157.
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- [68] Z. Wronicz, Construction of an orthonormal basis in the space of functions analytic in a disc and of class C^n in its closure, ibid. 21 (1979), 91-96.
- [69] Z. Wronicz, Interpolation by complex cubic splines, in: Constructive Function Theory '77, Bl. Sendov and D. Vačov (eds.), Publ. House of the Bulgar. Acad. Sci., Sofia 1980, 549-558.
- [70] Z. Wronicz, On approximation by analytic splines, in: Approximation and Function Spaces, Z. Ciesielski (ed.), PWN and North-Holland, Warszawa-Amsterdam 1981, 867-879.
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- [75] Z. Wronicz, The Marchaud inequality for generalized moduli of smoothness, in: Rational Approximation and its Applications in Mathematics and Physics, J. Gilewicz, M. Pindor, W. Siemaszko (eds.), Lecture Notes in Math. 1237, Springer, 1987, 134-144.
- [76] Z. Wronicz, On equivalence of spline bases in L_p spaces, Bull. Polish Acad. Sci. Math. 36 (1988), 273-278.
- [77] Z. Wronicz, Systems conjugate to biorthogonal spline systems, ibid., 279-288.
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Uwagi
1985 Mathematics Subject Classification: 41A15, 46E15, 46B15
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ISSN
0012-3862
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