17

When dealing with overlapping high density scatter or line plots of different colors it can be convenient to implement additive blending schemes, where the RGB colors of each marker add together to produce the final color in the canvas. This is a common operation in 2D and 3D render engines.

However, in Matplotlib I've only found support for alpha/opacity blending. Is there any roundabout way of doing it or am I stuck with rendering to bitmap and then blending them in some paint program?

Edit: Here's some example code and a manual solution.

This will produce two partially overlapping random distributions:

x1 = randn(1000)
y1 = randn(1000)
x2 = randn(1000) * 5
y2 = randn(1000)
scatter(x1,y1,c='b',edgecolors='none')
scatter(x2,y2,c='r',edgecolors='none')

This will produce in matplotlib the following: scatter - no blend

As you can see, there are some overlapping blue points that are occluded by red points and we would like to see them. By using alpha/opacity blending in matplotlib, you can do:

scatter(x1,y1,c='b',edgecolors='none',alpha=0.5)
scatter(x2,y2,c='r',edgecolors='none',alpha=0.5)

Which will produce the following:

scatter - alpha blend (0.5)

But what I really want is the following:

scatter - additive blend

I can do it manually by rendering each plot independently to a bitmap:

xlim = plt.xlim()
ylim = plt.ylim()
scatter(x1,y1,c='b',edgecolors='none')
plt.xlim(xlim)
plt.ylim(ylim)
scatter(x2,y2,c='r',edgecolors='none')
plt.xlim(xlim)
plt.ylim(ylim)
plt.savefig(r'scatter_blue.png',transparent=True)
plt.savefig(r'scatter_red.png',transparent=True)

Which gives me the following images:

scatter - red/blue channels

What you can do then is load them as independent layers in Paint.NET/PhotoShop/gimp and just additive blend them.

Now ideal would be to be able to do this programmatically in Matplotlib, since I'll be processing hundreds of these!

  • The easiest might be to make a 2-D histogram. Please show us some example code and data to get us started. – Bas Swinckels Nov 2 '14 at 17:58
  • Thanks, just added some example code and the steps for a manual solution. – glopes Nov 2 '14 at 18:31
  • Thanks, much better question now, will see what I can do. – Bas Swinckels Nov 2 '14 at 19:13
  • I don't think this is a mode we support out-of-the-box. – tacaswell Nov 3 '14 at 4:29
  • I also don't understand your comment about 'fixed color background' it should be dong blending against what is currently on the canvas. – tacaswell Nov 3 '14 at 4:30
9

If you only need an image as the result, you can get the canvas buffer as a numpy array, and then do the blending, here is an example:

from matplotlib import pyplot as plt
import numpy as np

fig, ax = plt.subplots()
ax.scatter(x1,y1,c='b',edgecolors='none')
ax.set_xlim(-4, 4)
ax.set_ylim(-4, 4)
ax.patch.set_facecolor("none")
ax.patch.set_edgecolor("none")
fig.canvas.draw()

w, h = fig.canvas.get_width_height()
img = np.frombuffer(fig.canvas.buffer_rgba(), np.uint8).reshape(h, w, -1).copy()

ax.clear()
ax.scatter(x2,y2,c='r',edgecolors='none')
ax.set_xlim(-4, 4)
ax.set_ylim(-4, 4)
ax.patch.set_facecolor("none")
ax.patch.set_edgecolor("none")
fig.canvas.draw()

img2 = np.frombuffer(fig.canvas.buffer_rgba(), np.uint8).reshape(h, w, -1).copy()

img[img[:, :, -1] == 0] = 0
img2[img2[:, :, -1] == 0] = 0

fig.clf()

plt.imshow(np.maximum(img, img2))
plt.subplots_adjust(0, 0, 1, 1)
plt.axis("off")
plt.show()

the result:

enter image description here

  • I was actually just checking out the buffer_rgba() functions when your answer came up. Yes, I think this is the best that can be done with Matplotlib for now. For some reason in my version of Matplotlib the end result is not as pretty (transparency is screwed up), but I'm sure that with a little tweaking I'll get it to work now. Thanks! – glopes Nov 3 '14 at 11:15
0

This feature is now supported by my matplotlib backend https://github.com/anntzer/mplcairo (master only):

import matplotlib; matplotlib.use("module://mplcairo.qt")
from matplotlib import pyplot as plt
from mplcairo import operator_t
import numpy as np

x1 = np.random.randn(1000)
y1 = np.random.randn(1000)
x2 = np.random.randn(1000) * 5
y2 = np.random.randn(1000)
fig, ax = plt.subplots()
# The figure and axes background must be made transparent.
fig.patch.set(alpha=0)
ax.patch.set(alpha=0)
pc1 = ax.scatter(x1, y1, c='b', edgecolors='none')
pc2 = ax.scatter(x2, y2, c='r', edgecolors='none')
operator_t.ADD.patch_artist(pc2)  # Use additive blending.
plt.show()

enter image description here

  • Is this your library? If so you should make it clear in your answer that you are the author – DavidG Mar 25 at 15:37
  • thanks for the note, done. – antony Mar 25 at 16:59

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.