# Newton’s interpolating polynomial [python]

I am trying to compute the finite divided differences of the following array using Newton's interpolating polynomial to determine y at x=8. The array is

``````x = 0  1  2  5.5  11  13  16  18

y=  0.5  3.134  5.9  9.9  10.2  9.35  7.2  6.2
``````

The pseudo code that I have is at http://imgur.com/gallery/Lm2KXxA/new. Are there any available pseudocode, algorithms or libraries I could use to tell me the answer?

Also I believe this is how to do the program in matlab http://imgur.com/gallery/L9wJaEH/new. I just can't figure out how to do it in python.

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That matlab code is pretty terrible (`for` loops all over the place instead of vectorizing), but you could turn it into similarly terrible numpy code by just changing most of the `()`s to `[]`s (for indexing) and making the indices go from 0 to `n-1` instead of 1 to `n`. – Dougal Feb 12 '13 at 1:40
It was in a book my roommate had. – Scrubatpython Feb 12 '13 at 1:44

## 1 Answer

Here is the python code. coef() function compute the finite divided difference coefficients, and the function Eval() evaluate the interpolation at a given node

import numpy as np import matplotlib.pyplot as plt

def coef(x, y): '''x : array of data points y : array of f(x) ''' x.astype(float) y.astype(float) n = len(x) a = [] for i in range(n): a.append(y[i])

``````for j in range(1, n):

for i in range(n-1, j-1, -1):
a[i] = float(a[i]-a[i-1])/float(x[i]-x[i-j])

return np.array(a) # return an array of coefficient
``````

def Eval(a, x, r):

`````` ''' a : array returned by function coef()
x : array of data points
r : the node to interpolate at  '''

x.astype(float)
n = len( a ) - 1
temp = a[n]
for i in range( n - 1, -1, -1 ):
temp = temp * ( r - x[i] ) + a[i]
return temp # return the y_value interpolation
``````
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