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 *[x*_{1}, x_{2}] would be in column 0:

*y*_{1} would be `s.c[3, 0]`

*b*_{1} would be `s.c[2, 0]`

*c*_{1} would be `s.c[1, 0]`

*d*_{1} would be `s.c[0, 0]`

.

Then for the second segment *[x*_{2}, x_{3}] you would have `s.c[3, 1]`

, `s.c[2, 1]`

, `s.c[1, 1]`

and `s.c[0, 1]`

for *y*_{2}, *b*_{2}, *c*_{2}, *d*_{2}, 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()
```