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\(C^k\)-reconstruction of surfaces from partial data. (English) Zbl 0971.86001

Summary: In this paper, we study the problem of constructing a smooth approximant of a surface defined by the equation \(z=f(x_1,x_2)\), the data being a finite set of patches on this surface. This problem occurs, for example, after geophysical processing such as migration of time-maps or depth-maps. The usual algorithms to solve this problem are picking points on the patches to get Lagrange data or trying to get local junctions on patches. But the first method does not use the continuous aspect of the data and the second one does not perform well to get a global regular approximant (\(C^1\) or more). As an approximant of \(f\), a discrete smoothing spline belonging to a suitable piecewise polynomial space is proposed. The originality of the method consists in the fidelity criterion used to fit the data, which takes into account their particular aspect (surface patches): the idea is to define a function that minimizes the volume located between the data patches and the function, and which is globally \(C^k\). We first demonstrate the new method on a theoretical aspect, and numerical results on real data are given.

MSC:

86-08 Computational methods for problems pertaining to geophysics
65D07 Numerical computation using splines
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