In a previous question (fastest way to use numpy.interp on a 2-D array) someone asked for the fastest way to implement the following:

np.array([np.interp(X[i], x, Y[i]) for i in range(len(X))])

assume X and Y are matrices with many rows so the for loop is costly. There is a nice solution in this case that avoids the for loop (see linked answer above).

I am faced with a very similar problem, but I am unclear on whether the for loop can be avoided in this case:

np.array([np.interp(x, X[i], Y[i]) for i in range(len(X))])

In other words, I want to use linear interpolation to upsample a large number of signals stored in the rows of two matrices X and Y. I was hoping to find a function in numpy or scipy (scipy.interpolate.interp1d) that supported this operation via broadcasting semantics but I so far can't seem to find one.

Other points:

  • If it helps, the rows X[i] and x are pre-sorted in my application. Also, in my case len(x) is quite a bit larger than len(X[i]).

  • The function scipy.signal.resample almost does what I want, but it doesn't use linear interpolation...

1 Answer 1


This is a vectorized approach that directly implements linear interpolation. First, for each x value and each i, j compute the weight w expressing how much of the interval (X[i, j], X[i, j+1]) is to the left of x.

  • If the entire interval is to the left of x, the weight of that interval is 1.
  • If none of the subinterval is to the left, the weight is 0
  • Otherwise, the weight is a number between 0 and 1, expressing the proportion of that interval to the left of x.

Then the value of PL interpolant is computed as Y[i, 0] + sum of differences dY[i, j] multiplied by the corresponding weight. The logic is to follow by how much the interpolant changes from interval to interval. The differences dY = np.diff(Y, axis=1) show how much it changes over the entire interval. Multiplication by the weight prorates that change accordingly.

Setup, with some small data arrays

import numpy as np
X = np.array([[0, 2, 5, 6, 9], [1, 3, 4, 7, 8]])
Y = np.array([[3, 5, 2, 4, 1], [8, 6, 9, 5, 4]])
x = np.linspace(1, 8, 20)

The computation

dX = np.diff(X, axis=1)
dY = np.diff(Y, axis=1)
w = np.clip((x - X[:, :-1, None])/dX[:, :, None], 0, 1)
y = Y[:, [0]] + np.sum(w*dY[:, :, None], axis=1)


This is only to show that the interpolation is correct. Blue points: original data, red ones are computed.

import matplotlib.pyplot as plt
plt.plot(x, y[0], 'ro')
plt.plot(X[0], Y[0], 'bo')
plt.plot(x, y[1], 'rd')
plt.plot(X[1], Y[1], 'bd')

PL interpolants

  • This assumes all elements of (X,Y) have the same length though :\ Feb 11, 2019 at 15:02

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.