# modify discrete LinearSegmentedColormap

I'm a climatologist and often plot anomalies of e.g. temperature fields using a "blue-to-white-to-red" colormap. To make the plots more readable, I discretize the colormap in a certain number of levels (bins) with a function which I "found" in the Internet (but I don't really understand it):

Something like this:

``````import matplotlib.pyplot as plt
import numpy as np
from matplotlib import cm
import matplotlib.colors as cols
from numpy.random import randn

def cmap_discretize(cmap, N):
colors_i = np.concatenate((np.linspace(0, 1., N), (0.,0.,0.,0.)))
colors_rgba = cmap(colors_i)
indices = np.linspace(0, 1., N+1)
cdict = {}
for ki,key in enumerate(('red','green','blue')):
cdict[key] = [ (indices[i], colors_rgba[i-1,ki], colors_rgba[i,ki]) for i in xrange(N+1) ]
# Return colormap object.
return cols.LinearSegmentedColormap(cmap.name + "_%d"%N, cdict, 1024)

cmap_disc= cmap_discretize(cm.RdBu_r,12)

fig, ax = plt.subplots()
data = np.clip(randn(250, 250), -1, 1)

cax = ax.pcolor(data, cmap=cmap_disc)
plt.colorbar(cax)

plt.show()
``````

This results in

Now I want to set the two middle-most segments (i.e. those two close to 0) to white because I don't want to show very small deviations.

My goal would be to end up with something similar to this:

I really have a hard time to figure out how these LinearSegmentedColormap can be modified accordingly. Can somebody help me with this?

-
Please read: matplotlib.org/api/… which has a clear description of how the color maps work. – tcaswell Oct 5 '13 at 15:37
And you might get some traction using the code at stackoverflow.com/questions/15399095/stacking-colormaps/… and passing in two descritized color maps. – tcaswell Oct 5 '13 at 15:43

Lets start by walking through the code you have

``````# get some uniformly sampled data, padded out a bit
colors_i = np.concatenate((np.linspace(0, 1., N), (0.,0.,0.,0.)))
# sample the input colormap at our sample points
colors_rgba = cmap(colors_i)
# indices for color map
indices = np.linspace(0, 1., N+1)
# dict to pass to the LinearSegmentedColormap
cdict = {}
# loop over the colors
for ki,key in enumerate(('red','green','blue')):
# in each color assemble a list that looks like
#[...,
# (indices[2], colors_rgba[1,ki], colors_rgba[2,ki]),
# (indices[3], colors_rgba[2,ki], colors_rgba[3,ki]),
# ....]
cdict[key] = [ (indices[i], colors_rgba[i-1,ki], colors_rgba[i,ki]) for i in xrange(N+1) ]
# The color for a number between [indices[2], indices[3]] are interpolated
# between colors_rgba[2,ki] and colors_rgba[2,ki] which are the same
# which is what gives you the discrete blocks.
# Construct and return colormap object.
return cols.LinearSegmentedColormap(cmap.name + "_%d"%N, cdict, 1024)
``````

So now the question is how to create a color map with a 'doubled' white band in the middle. I would change the function bit to have it take in two color maps (top and bottom)

``````import matplotlib.pyplot as plt
import numpy as np
from matplotlib import cm
import matplotlib.colors as cols
from numpy.random import randn

def cmap_double_discretize(cmap_bottom, cmap_top, N, split=.5):
"""
Generates a descritized color map using two existing color maps

Parameters
----------
cmap_bottom : cmap
The bottom cmap

cmap_top : cmap
The top cmap

N : int
The number of bins in each color map

split : float, optional
Where to join the maps, must be in [0, 1]
"""
# sanity check
assert split < 1 and split > 0
# set up the data structure
cdict = {lab: [] for lab in ('red','green','blue')}
# do this in a fancy loop to a) save typing, b) make it easy to
# retrofit to do arbitrary splits
for cmap, ends in zip((cmap_bottom, cmap_top), ((0, split), (split, 1))):

# run over the _whole_ range for each color map
colors_i = np.concatenate((np.linspace(0, 1., N), (0.,0.,0.,0.)))
# map the color
colors_rgba = cmap(colors_i)
# get the values
indices = np.linspace(ends[0], ends[1], N+1, endpoint=True)

for ki,key in enumerate(('red','green','blue')):
cdict[key].extend((indices[i], colors_rgba[i-1,ki], colors_rgba[i,ki]) for i in xrange(N+1))
#    print cdict
# Return colormap object.
return cols.LinearSegmentedColormap(cmap.name + "_%d"%N, cdict, 1024)

red_cdict = {'red': [(0, 0, 1),
(1, 1, 0)],
'blue': [(0, 0, 0),
(1, 1, 0)],
'green': [(0, 0, 0),
(1, 1, 0)]}

blue_cdict = {'blue': [(0, 0, 1),
(1, 1, 0),],
'red': [(0, 0, 1),
(1, 0, 0)],
'green': [(0, 0, 1),
(1, 0, 0)]}
red_cmap = cols.LinearSegmentedColormap('red', red_cdict, 1024)
blue_cmap = cols.LinearSegmentedColormap('blue', blue_cdict, 1024)

test_cmap = cmap_double_discretize(red_cmap, blue_cmap, 6)
# these don't actually go to white!
# test_cmap = cmap_double_discretize(cm.get_cmap('Reds_r'), cm.get_cmap('Blues'), 6)

fig, ax = plt.subplots()
data = np.clip(randn(250, 250), -1, 1)

cax = ax.pcolor(data, cmap=test_cmap)
plt.colorbar(cax)

plt.show()
``````

You can easily modify this to split across more than two color maps.

-
this also works, but does not support predefined colormaps with white in the middle (like bwr,seismic,RdBu,RdGy...). Still many thanks for your effort – Raphael Roth Oct 5 '13 at 16:49

The function you have found builds a data structure (in `cdict`) for defining a LinearSegmentedColormap with segments that don't perform any interpolation (i.e., `y1` in row `i` is always identical to `y0` in row `i+1`, and this gives the constant, or discrete, color "bands").

`cdict` is a weird data structure, a dictionary which contains the keys `'red'`, `'green'` and `'blue'`. The value for each of these keys is a list structure containing tuples of the form `(x, y0, y1)`. `x` is the color map coordinate, which is some floating point number between 0 and 1. `y0` is the color value on the "left" side of `x`, and `y1` is the color value on the "right" side of `x`. Colors are linearly interpolated in bands between consecutive values of `x`; if the first tuple is given by `(0, A, B)` and the second tuple by `(X, C, D)`, then the color of a point `t` between `0` and `X` will be given by `(t - 0) / (X - 0) * (C - B) + B`.

For your purposes, your function works pretty well, but needs to have the "bands" near the middle of the color map replaced with a white color. You can try something like the following:

``````def cmap_discretize(cmap, N):
colors_i = np.concatenate((np.linspace(0, 1., N), (0.,0.,0.,0.)))
colors_rgba = cmap(colors_i)
indices = np.linspace(0, 1., N+1)
cdict = {}
for ki,key in enumerate(('red','green','blue')):
cdict[key] = [ (indices[i], colors_rgba[i-1,ki], colors_rgba[i,ki]) for i in xrange(N+1) ]
# "white out" the bands closest to the middle
num_middle_bands = 2 - (N % 2)
middle_band_start_idx = (N - num_middle_bands) // 2
for middle_band_idx in range(middle_band_start_idx,
middle_band_start_idx + num_middle_bands):
for key in cdict.keys():
old = cdict[key][middle_band_idx]
cdict[key][middle_band_idx] = old[:2] + (1.,)
old = cdict[key][middle_band_idx + 1]
cdict[key][middle_band_idx + 1] = old[:1] + (1.,) + old[2:]
# Return colormap object.
return cols.LinearSegmentedColormap(cmap.name + "_%d"%N, cdict, 1024)
``````
-
this is great, but I still need to work it through to understand it – Raphael Roth Oct 5 '13 at 16:47
I'm a little leary of reaching in squashing the colors like this because you are making the color map non-linear in a really non-transparent way. – tcaswell Oct 5 '13 at 17:01