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I am generating a graph of a cubic spline through a given set of data points:

import matplotlib.pyplot as plt
import numpy as np
from scipy import interpolate

x = np.array([1, 2, 4, 5])  # sort data points by increasing x value
y = np.array([2, 1, 4, 3])
arr = np.arange(np.amin(x), np.amax(x), 0.01)
s = interpolate.CubicSpline(x, y)
plt.plot(x, y, 'bo', label='Data Point')
plt.plot(arr, s(arr), 'r-', label='Cubic Spline')
plt.legend()
plt.show()

How can I get the spline equations from CubicSpline? I need the equations in the form:

I've attempted various methods to get the coefficients, but they all use data that was obtained using different data other than just the data points.

2 Answers 2

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From the documentation:

c (ndarray, shape (4, n-1, ...)) Coefficients of the polynomials on each segment. The trailing dimensions match the dimensions of y, excluding axis. For example, if y is 1-d, then c[k, i] is a coefficient for (x-x[i])**(3-k) on the segment between x[i] and x[i+1].

So in your example, the coefficients for the first segment [x1, x2] would be in column 0:

  • y1 would be s.c[3, 0]
  • b1 would be s.c[2, 0]
  • c1 would be s.c[1, 0]
  • d1 would be s.c[0, 0].

Then for the second segment [x2, x3] you would have s.c[3, 1], s.c[2, 1], s.c[1, 1] and s.c[0, 1] for y2, b2, c2, d2, and so on and so forth.

For example:

x = np.array([1, 2, 4, 5])  # sort data points by increasing x value
y = np.array([2, 1, 4, 3])
arr = np.arange(np.amin(x), np.amax(x), 0.01)
s = interpolate.CubicSpline(x, y)

fig, ax = plt.subplots(1, 1)
ax.hold(True)
ax.plot(x, y, 'bo', label='Data Point')
ax.plot(arr, s(arr), 'k-', label='Cubic Spline', lw=1)

for i in range(x.shape[0] - 1):
    segment_x = np.linspace(x[i], x[i + 1], 100)
    # A (4, 100) array, where the rows contain (x-x[i])**3, (x-x[i])**2 etc.
    exp_x = (segment_x - x[i])[None, :] ** np.arange(4)[::-1, None]
    # Sum over the rows of exp_x weighted by coefficients in the ith column of s.c
    segment_y = s.c[:, i].dot(exp_x)
    ax.plot(segment_x, segment_y, label='Segment {}'.format(i), ls='--', lw=3)

ax.legend()
plt.show()

enter image description here

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Edit: Since the coefficients are accessible as an attribute (see @ali_m's answer) the approach shown here is unnecessarily indirect. I'm leaving it online should somebody using a more opaque library ever stumble over this question.

One way would be to evaluate at the node of interest:

coeffs = [s(2)] + [s.derivative(i)(2) / misc.factorial(i) for i in range(1,4)]
s(2.5)
# -> array(1.59375)
sum(coeffs[i]*(2.5-2)**i for i in range(4))
# -> 1.59375

Strictly speaking the higher derivatives don't exist at the nodes but scipy appears to return the right one-sided derivative, so it works even though it shouldn't.

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  • I tried running this with a sample and the answer for the coefficients is not correct.
    – jshapy8
    Commented Apr 17, 2017 at 21:35
  • @jshapy8 would you be kind enough to share that sample? On the sample you posted it seems to work well enough. Commented Apr 17, 2017 at 21:46
  • On the sample I posted, the coefficients for S_1 should be as follows: 2, (-13/8), 0, (5/8) on [1,2]
    – jshapy8
    Commented Apr 17, 2017 at 21:48
  • @jshapy8 I get the same coefficients with my method and with @ali_m's method. If I evaluate your coefficients at 1.3, say, I do not get the same as s(1.3). Commented Apr 17, 2017 at 22:02
  • @ I don't know, different boundary conditions probably. You do realise that the coefficients depend on the boundary conditions? Why don't you try your coefficients and evaluate at a few points in [1,2) and then evaluate s at the same points? Commented Apr 17, 2017 at 22:14

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