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Generate a heatmap in MatPlotLib using a scatter data set

I have a set of X,Y data points (about 10k) that are easy to plot as a scatter plot but that I would like to represent as a heatmap.

I looked through the examples in MatPlotLib and they all seem to already start with heatmap cell values to generate the image.

Is there a method that converts a bunch of x,y, all different, to a heatmap (where zones with higher frequency of x,y would be "warmer")?

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If you don't want hexagons, you can use numpy's `histogram2d` function:

``````import numpy as np
import numpy.random
import matplotlib.pyplot as plt

# Generate some test data
x = np.random.randn(8873)
y = np.random.randn(8873)

heatmap, xedges, yedges = np.histogram2d(x, y, bins=50)
extent = [xedges[0], xedges[-1], yedges[0], yedges[-1]]

plt.clf()
plt.imshow(heatmap, extent=extent)
plt.show()
``````

This makes a 50x50 heatmap. If you want, say, 512x384, you can put `bins=(512, 384)` in the call to `histogram2d`.

Example:

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I don't mean to be an idiot, but how do you actually have this output to a PNG/PDF file instead of only displaying in an interactive IPython session? I'm trying to get this as some sort of normal `axes` instance, where I can add a title, axis labels, etc. and then do the normal `savefig()` like I would do for any other typical matplotlib plot. – gotgenes Jul 15 '11 at 19:19
@gotgenes: doesn't `plt.savefig('filename.png')` work? If you want to get an axes instance, use Matplotlib's object-oriented interface: `fig = plt.figure()` `ax = fig.gca()` `ax.imshow(...)` `fig.savefig(...)` – ptomato Jul 16 '11 at 17:05
Indeed, thanks! I guess I do not fully understand that `imshow()` is on the same category of functions as `scatter()`. I honestly don't understand why `imshow()` converts a 2d array of floats into blocks of appropriate color, whereas I do understand what `scatter()` is supposed to do with such an array. – gotgenes Jul 21 '11 at 19:10
A warning about using imshow for plotting a 2d histogram of x/y values like this: by default, imshow plots the origin in the upper left corner and transposes the image. What I would do to get the same orientation as a scatter plot is `plt.imshow(heatmap.T, extent=extent, origin = 'lower')` – Jamie Nov 18 '13 at 13:29
For those wanting to do a logarithmic colorbar see this question stackoverflow.com/questions/17201172/… and simply do `from matplotlib.colors import LogNorm` `plt.imshow(heatmap, norm=LogNorm())` `plt.colorbar()` – tommy.carstensen Mar 16 '15 at 20:25

In Matplotlib lexicon, i think you want a hexbin plot.

If you're not familiar with this type of plot, it's just a bivariate histogram in which the xy-plane is tessellated by a regular grid of hexagons.

So from a histogram, you can just count the number of points falling in each hexagon, discretiize the plotting region as a set of windows, assign each point to one of these windows; finally, map the windows onto a color array, and you've got a hexbin diagram.

Though less commonly used than e.g., circles, or squares, that hexagons are a better choice for the geometry of the binning container is intuitive:

• hexagons have nearest-neighbor symmetry (e.g., square bins don't, e.g., the distance from a point on a square's border to a point inside that square is not everywhere equal) and

• hexagon is the highest n-polygon that gives regular plane tessellation (i.e., you can safely re-model your kitchen floor with hexagonal-shaped tiles because you won't have any void space between the tiles when you are finished--not true for all other higher-n, n >= 7, polygons).

(Matplotlib uses the term hexbin plot; so do (AFAIK) all of the plotting libraries for R; still i don't know if this is the generally accepted term for plots of this type, though i suspect it's likely given that hexbin is short for hexagonal binning, which is describes the essential step in preparing the data for display.)

``````from matplotlib import pyplot as PLT
from matplotlib import cm as CM
from matplotlib import mlab as ML
import numpy as NP

n = 1e5
x = y = NP.linspace(-5, 5, 100)
X, Y = NP.meshgrid(x, y)
Z1 = ML.bivariate_normal(X, Y, 2, 2, 0, 0)
Z2 = ML.bivariate_normal(X, Y, 4, 1, 1, 1)
ZD = Z2 - Z1
x = X.ravel()
y = Y.ravel()
z = ZD.ravel()
gridsize=30
PLT.subplot(111)

# if 'bins=None', then color of each hexagon corresponds directly to its count
# 'C' is optional--it maps values to x-y coordinates; if 'C' is None (default) then
# the result is a pure 2D histogram

PLT.hexbin(x, y, C=z, gridsize=gridsize, cmap=CM.jet, bins=None)
PLT.axis([x.min(), x.max(), y.min(), y.max()])

cb = PLT.colorbar()
cb.set_label('mean value')
PLT.show()
``````

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What does it mean that "hexagons have nearest-neighbor symmetry"? You say that "the distance from a point on a square's border and a point inside that square is not everywhere equal" but distance to what? – Jaan Apr 11 '14 at 16:04
For a hexagon, the distance from center to a vertex joining two sides is also longer than from center to middle of a side, only the ratio is smaller (2/sqrt(3) ≈ 1.15 for hexagon vs. sqrt(2) ≈ 1.41 for square). The only shape where the distance from the center to every point on the border is equal is the circle. – Jaan May 25 '14 at 18:46
@Jaan For a hexagon, every neighbor is at the same distance. There is no issue with 8-neighborhood or 4-neighborhood. No diagonal neighbors, just one kind of neighbor. – isarandi Mar 8 '15 at 16:06
@doug How do you choose the `gridsize=` parameter. I would like to choose it such, so that the hexagons just touch without overlapping. I noticed that `gridsize=100` would produce smaller hexagons, but how to choose the proper value? – Alexander Cska Apr 19 at 9:05

If you are using 1.2.x

```x = randn(100000)
y = randn(100000)
hist2d(x,y,bins=100);
```

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Instead of using np.hist2d, which in general produces quite ugly histograms, I would like to recycle py-sphviewer, a python package for rendering particle simulations using an adaptive smoothing kernel and that can be easily installed from pip (see webpage documentation). Consider the following code, which is based on the example:

``````import numpy as np
import numpy.random
import matplotlib.pyplot as plt
import sphviewer as sph

def myplot(x, y, nb=32, xsize=500, ysize=500):
xmin = np.min(x)
xmax = np.max(x)
ymin = np.min(y)
ymax = np.max(y)

x0 = (xmin+xmax)/2.
y0 = (ymin+ymax)/2.

pos = np.zeros([3, len(x)])
pos[0,:] = x
pos[1,:] = y
w = np.ones(len(x))

P = sph.Particles(pos, w, nb=nb)
S = sph.Scene(P)
S.update_camera(r='infinity', x=x0, y=y0, z=0,
xsize=xsize, ysize=ysize)
R = sph.Render(S)
R.set_logscale()
img = R.get_image()
extent = R.get_extent()
for i, j in zip(xrange(4), [x0,x0,y0,y0]):
extent[i] += j
print extent
return img, extent

fig = plt.figure(1, figsize=(10,10))

# Generate some test data
x = np.random.randn(1000)
y = np.random.randn(1000)

#Plotting a regular scatter plot
ax1.plot(x,y,'k.', markersize=5)
ax1.set_xlim(-3,3)
ax1.set_ylim(-3,3)

heatmap_16, extent_16 = myplot(x,y, nb=16)
heatmap_32, extent_32 = myplot(x,y, nb=32)
heatmap_64, extent_64 = myplot(x,y, nb=64)

ax2.imshow(heatmap_16, extent=extent_16, origin='lower', aspect='auto')
ax2.set_title("Smoothing over 16 neighbors")

ax3.imshow(heatmap_32, extent=extent_32, origin='lower', aspect='auto')
ax3.set_title("Smoothing over 32 neighbors")

#Make the heatmap using a smoothing over 64 neighbors
ax4.imshow(heatmap_64, extent=extent_64, origin='lower', aspect='auto')
ax4.set_title("Smoothing over 64 neighbors")

plt.show()
``````

which produces the following image:

As you see, the images look pretty nice, and we are able to identify different substructures on it. These images are constructed spreading a given weight for every point within a certain domain, defined by the smoothing length, which in turns is given by the distance to the closer nb neighbor (I've chosen 16, 32 and 64 for the examples). So, higher density regions typically are spread over smaller regions compared to lower density regions.

The function myplot is just a very simple function that I've written in order to give the x,y data to py-sphviewer to do the magic.

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this answer Efficient method of calculating density of irregularly spaced points introduced more methods about how to do it more efficiently and precisely. hope it can helps

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Make a 2-dimensional array that corresponds to the cells in your final image, called say `heatmap_cells` and instantiate it as all zeroes.

Choose two scaling factors that define the difference between each array element in real units, for each dimension, say `x_scale` and `y_scale`. Choose these such that all your datapoints will fall within the bounds of the heatmap array.

For each raw datapoint with `x_value` and `y_value`:

`heatmap_cells[floor(x_value/x_scale),floor(y_value/y_scale)]+=1`

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Numpy has a function for that... – ptomato Mar 17 '10 at 9:22