Construction of new cubic Bézier-like triangular patches with application in scattered data interpolation

This paper discusses the functional scattered data interpolation to interpolate the general scattered data. Compared with the previous works, we construct a new cubic Bézier-like triangular basis function controlled by three shape parameters. This is an advantage compared with the existing schemes s...

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Bibliographic Details
Published in:Advances in difference equations 2020-04, Vol.2020 (1), p.1-22, Article 151
Main Authors: Karim, Samsul Ariffin Abdul, Saaban, Azizan, Skala, Vaclav, Ghaffar, Abdul, Nisar, Kottakkaran Sooppy, Baleanu, Dumitru
Format: Article
Language:English
Subjects:
Analysis
Bézier triangular
Continuity
Cubic Bézier-like
Delaunay triangulation
Difference and Functional Equations
Error analysis
Functional Analysis
Interpolation
Mathematics
Mathematics and Statistics
Meshless methods
Ordinary Differential Equations
Parameters
Partial Differential Equations
Patches
Patches (structures)
Radial basis function
Scattered data interpolation
Thin plates
Triangles
Visualization
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Summary:This paper discusses the functional scattered data interpolation to interpolate the general scattered data. Compared with the previous works, we construct a new cubic Bézier-like triangular basis function controlled by three shape parameters. This is an advantage compared with the existing schemes since it gives more flexibility for the shape design in geometric modeling. By choosing some suitable value of the parameters, this new triangular basis is reduced to the cubic Ball and cubic Bézier triangular patches, respectively. In order to apply the proposed bases to general scattered data, firstly the data is triangulated using Delaunay triangulation. Then the sufficient condition for C 1 continuity using cubic precision method on each adjacent triangle is implemented. Finally, the interpolation scheme is constructed based on a convex combination between three local schemes of the cubic Bézier-like triangular patches. The detail comparison in terms of maximum error and coefficient of determination r 2 with some existing meshfree methods i.e. radial basis function (RBF) such as linear, thin plate spline (TPS), Gaussian, and multiquadric are presented. From graphical results, the proposed scheme gives more visually pleasing interpolating surfaces compared with all RBF methods. Based on error analysis, for all four functions, the proposed scheme is better than RBFs except for data from the third function. Overall, the proposed scheme gives r 2 value between 0.99920443 and 0.99999994. This is very good for surface fitting for a large scattered data set.
ISSN:1687-1847
1687-1839
1687-1847
DOI:10.1186/s13662-020-02598-w