Lagrange interpolation in Python

I want to interpolate a polynomial with the Lagrange method, but this code doesn't work:

def interpolate(x_values, y_values):
    def _basis(j):
        p = [(x - x_values[m])/(x_values[j] - x_values[m]) for m in xrange(k + 1) if m != j]
        return reduce(operator.mul, p)

    assert len(x_values) != 0 and (len(x_values) == len(y_values)), 'x and y cannot be empty and must have the same length'

    k = len(x_values)
    return sum(_basis(j) for j in xrange(k))

I followed Wikipedia, but when I run it I 开发者_JAVA百科receive an IndexError at line 3!

Thanks

Try

def interpolate(x, x_values, y_values):
    def _basis(j):
        p = [(x - x_values[m])/(x_values[j] - x_values[m]) for m in xrange(k) if m != j]
        return reduce(operator.mul, p)
    assert len(x_values) != 0 and (len(x_values) == len(y_values)), 'x and y cannot be empty and must have the same length'
    k = len(x_values)
    return sum(_basis(j)*y_values[j] for j in xrange(k))

You can confirm it as follows:

>>> interpolate(1,[1,2,4],[1,0,2])
1.0
>>> interpolate(2,[1,2,4],[1,0,2])
0.0
>>> interpolate(4,[1,2,4],[1,0,2])
2.0
>>> interpolate(3,[1,2,4],[1,0,2])
0.33333333333333331

So the result is the interpolated value based on the polynomial that goes through the points given. In this case, the 3 points define a parabola and the first 3 tests show that the stated y_value is returned for the given x_value.

I'm almost a decade late to the party, but I found this searching for a simple implementation of Lagrange interpolation. @smichr's answer is great, but the Python is a little outdated, and I also wanted something that would work nicely with np.ndarrays so I could do easy plotting. Maybe others will find this useful:

import numpy as np
import matplotlib.pyplot as plt


class LagrangePoly:

    def __init__(self, X, Y):
        self.n = len(X)
        self.X = np.array(X)
        self.Y = np.array(Y)

    def basis(self, x, j):
        b = [(x - self.X[m]) / (self.X[j] - self.X[m])
             for m in range(self.n) if m != j]
        return np.prod(b, axis=0) * self.Y[j]

    def interpolate(self, x):
        b = [self.basis(x, j) for j in range(self.n)]
        return np.sum(b, axis=0)


X  = [-9, -4, -1, 7]
Y  = [5, 2, -2, 9]

plt.scatter(X, Y, c='k')

lp = LagrangePoly(X, Y)

xx = np.arange(-100, 100) / 10

plt.plot(xx, lp.basis(xx, 0))
plt.plot(xx, lp.basis(xx, 1))
plt.plot(xx, lp.basis(xx, 2))
plt.plot(xx, lp.basis(xx, 3))
plt.plot(xx, lp.interpolate(xx), linestyle=':')
plt.show()

Check the indices, Wikipedia says "k+1 data points", but you're setting k = len(x_values) where it should be k = len(x_values) - 1 if you followed the formula exactly.

This code is compatible with Python 3:

def Lagrange (Lx, Ly):
    x=sympy.symbols('x')
    if  len(Lx)!= len(Ly):
        return 1
    y=0
    for k in range ( len(Lx) ):
        t=1
        for j in range ( len(Lx) ):
            if j != k:
                t=t* ( (x-Lx[j]) /(Lx[k]-Lx[j]) )
        y+= t*Ly[k]
    return y