Critical lengths of cycloidal spaces are zeros of Bessel functions
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Publication:1697292
DOI10.1007/s10092-017-0239-yzbMath1382.41001OpenAlexW2761933223MaRDI QIDQ1697292
J. M. Carnicer, Esmeralda Mainar, Juan Manuel Peña
Publication date: 15 February 2018
Published in: Calcolo (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1007/s10092-017-0239-y
Trigonometric approximation (42A10) Numerical interpolation (65D05) Interpolation in approximation theory (41A05) Approximation by polynomials (41A10) Computer-aided design (modeling of curves and surfaces) (65D17)
Related Items (7)
Algorithm 1020: Computation of Multi-Degree Tchebycheffian B-Splines ⋮ Tchebycheffian B-splines in isogeometric Galerkin methods ⋮ Spherical Bessel functions and critical lengths ⋮ Dimension elevation is not always corner-cutting ⋮ A remarkable Wronskian with application to critical lengths of cycloidal spaces ⋮ Critical length: an alternative approach ⋮ Accurate algorithms for Bessel matrices
Cites Work
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- On the critical lengths of cycloidal spaces
- Generalized B-splines as a tool in isogeometric analysis
- Bernstein operators for extended Chebyshev systems
- Shape preserving properties of generalized Bernstein operators on extended Chebyshev spaces
- Totally positive bases for shape preserving curve design and optimality of \(B\)-splines
- C-curves: An extension of cubic curves
- Shape preserving representations for trigonometric polynomial curves
- Critical length for design purposes and extended Chebyshev spaces
- Greville abscissae of totally positive bases
- A class of Bézier-like curves
- On a class of weak Tchebycheff systems
- Shape preserving alternatives to the rational Bézier model
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