Constructs a polynomial that passes through a given set of points. Allows evaluation of the polynomial, efficient changing of the y values to be interpolated, and updating by adding more x values. For reasons of numerical stability, this function does not compute the coefficients of the polynomial.
The values yi need to be provided before the function is evaluated, but none of the preprocessing depends on them, so rapid updates are possible.
This class uses a "barycentric interpolation" method that treats the problem as a special case of rational function interpolation. This algorithm is quite stable, numerically, but even in a world of exact computation, unless the x coordinates are chosen very carefully - Chebyshev zeros (e.g., cos(i*pi/n)) are a good choice - polynomial interpolation itself is a very ill-conditioned process due to the Runge phenomenon.
Based on Berrut and Trefethen 2004, "Barycentric Lagrange Interpolation".
1-D array of x coordinates of the points the polynomial should pass through
The y coordinates of the points the polynomial should pass through. If None, the y values will be supplied later via the :None:None:`set_y` method.
Axis in the yi array corresponding to the x-coordinate values.
The interpolating polynomial for a set of points
The following pages refer to to this document either explicitly or contain code examples using this.
scipy.interpolate._polyint.barycentric_interpolate
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