Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I'm trying to use the scipy.stats.gaussian_kde class to smooth out some discrete data collected with latitude and longitude information, so it shows up as somewhat similar to a contour map in the end, where the high densities are the peak and low densities are the valley.

I'm having a hard time putting a two-dimensional dataset into the gaussian_kde class. I've played around to figure out how it works with 1 dimensional data, so I thought 2 dimensional would be something along the lines of:

from scipy import stats
from numpy import array
data = array([[1.1, 1.1],
              [1.2, 1.2],
              [1.3, 1.3]])
kde = stats.gaussian_kde(data)

which is saying that I have 3 points at [1.1, 1.1], [1.2, 1.2], [1.3, 1.3]. and I want to have the kernel density estimation using from 1 to 3 using width of 1 on x and y axis.

When creating the gaussian_kde, it keeps giving me this error:

raise LinAlgError("singular matrix")
numpy.linalg.linalg.LinAlgError: singular matrix

Looking into the source code of gaussian_kde, I realize that the way I'm thinking about what dataset means is completely different from how the dimensionality is calculate, but I could not find any sample code showing how multi-dimension data works with the module. Could someone help me with some sample ways to use gaussian_kde with multi-dimensional data?

share|improve this question
Try it with data that's not all in a line. I'm not sure if it should fail for that, or if it's a bug. – endolith Jun 20 '11 at 2:35

This example seems to be what you're looking for:

import numpy as np
import scipy.stats as stats
from matplotlib.pyplot import imshow

# Create some dummy data
rvs = np.append(stats.norm.rvs(loc=2,scale=1,size=(2000,1)),

kde = stats.kde.gaussian_kde(rvs.T)

# Regular grid to evaluate kde upon
x_flat = np.r_[rvs[:,0].min():rvs[:,0].max():128j]
y_flat = np.r_[rvs[:,1].min():rvs[:,1].max():128j]
x,y = np.meshgrid(x_flat,y_flat)
grid_coords = np.append(x.reshape(-1,1),y.reshape(-1,1),axis=1)

z = kde(grid_coords.T)
z = z.reshape(128,128)


enter image description here

Axes need fixing, obviously.

You can also do a scatter plot of the data with


enter image description here

share|improve this answer and for example – endolith Jun 20 '11 at 16:44
when you say, axis need fixing, what do you mean? Because I am doing the same with a data and for some reason it gives back some excess below and above the min and max of the data – ThePredator Jun 13 '14 at 22:48
@Srivatsan: I think I just meant that it should have a more square aspect ratio – endolith Jun 14 '14 at 1:25

I think you are mixing up kernel density estimation with interpolation or maybe kernel regression. KDE estimates the distribution of points if you have a larger sample of points.

I'm not sure which interpolation you want, but either the splines or rbf in scipy.interpolate will be more appropriate.

If you want one-dimensional kernel regression, then you can find a version in scikits.statsmodels with several different kernels.

update: here is an example (if this is what you want)

>>> data = 2 + 2*np.random.randn(2, 100)
>>> kde = stats.gaussian_kde(data)
>>> kde.evaluate(np.array([[1,2,3],[1,2,3]]))
array([ 0.02573917,  0.02470436,  0.03084282])

gaussian_kde has variables in rows and observations in columns, so reversed orientation from the usual in stats. In your example, all three points are on a line, so it has perfect correlation. That is, I guess, the reason for the singular matrix.

Adjusting the array orientation and adding a small noise, the example works, but still looks very concentrated, for example you don't have any sample point near (3,3):

>>> data = np.array([[1.1, 1.1],
              [1.2, 1.2],
              [1.3, 1.3]]).T
>>> data = data + 0.01*np.random.randn(2,3)
>>> kde = stats.gaussian_kde(data)
>>> kde.evaluate(np.array([[1,2,3],[1,2,3]]))
array([  7.70204299e+000,   1.96813149e-044,   1.45796523e-251])
share|improve this answer
I'm not a statistician, but my reading of KDE and kernel regression and jet's mention of "contour map" makes me think KDE is what is meant. – endolith May 25 '11 at 14:40

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

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