# Change colorbar gradient in matplotlib

I have a grid of weights (Y) evolving with time (X):

I cannot distinguish correctly the variations of weights as the distribution is asymmetric between positive and negative weights; the null weights should be recognized as it means the given variables are not used.

For these reasons, I would like to change the color gradient to get something like those (either a or b):

Any idea on how to approach this?

A colorbar in matplotlib maps number between 0 and 1 to a color. In order to map other numbers to colors you need a normalization to the range `[0,1]` first. This is usually done automatically from the minimum and maximum data, or by using `vmin` and `vmax` arguments to the respective plotting function. Internally a normalization instance `matplotlib.colors.Normalize` is used to perform the normalization and by default a linear scale between `vmin` and `vmax` is assumed.

Here you want a nonlinear scale, which (a) shifts the middle point to some specified value, and (b) squeezes the colors around that value.

The idea can now be to subclass `matplotlib.colors.Normalize` and let it return a a mapping which fulfills the criteria (a) and (b).

An option might be the combination of two root functions as shown below.

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

class SqueezedNorm(matplotlib.colors.Normalize):
def __init__(self, vmin=None, vmax=None, mid=0, s1=2, s2=2, clip=False):
self.vmin = vmin # minimum value
self.mid  = mid  # middle value
self.vmax = vmax # maximum value
self.s1=s1; self.s2=s2
f = lambda x, zero,vmax,s: np.abs((x-zero)/(vmax-zero))**(1./s)*0.5
self.g = lambda x, zero,vmin,vmax, s1,s2: f(x,zero,vmax,s1)*(x>=zero) - \
f(x,zero,vmin,s2)*(x<zero)+0.5
matplotlib.colors.Normalize.__init__(self, vmin, vmax, clip)

def __call__(self, value, clip=None):
r = self.g(value, self.mid,self.vmin,self.vmax, self.s1,self.s2)

fig, (ax, ax2, ax3) = plt.subplots(nrows=3,
gridspec_kw={"height_ratios":[3,2,1], "hspace":0.25})

x = np.linspace(-13,4, 110)
norm=SqueezedNorm(vmin=-13, vmax=4, mid=0, s1=1.7, s2=4)

line, = ax.plot(x, norm(x))
ax.margins(0)
ax.set_ylim(0,1)

im = ax2.imshow(np.atleast_2d(x).T, cmap="Spectral_r", norm=norm, aspect="auto")
cbar = fig.colorbar(im ,cax=ax3,ax=ax2, orientation="horizontal")
``````

The function is chosen such that independent of its parameters it will map any range onto the range `[0,1]`, such that a colormap can be used. The parameter `mid` determines which value should be mapped to the middle of the colormap. This would be `0` in this case. The parameters `s1` and `s2` determine how squeezed the colormap is in both directions.

Setting `mid = np.mean(vmin, vmax), s1=1, s2=1` would recover the original scaling.

In order to choose good parameters, one may use some Sliders to see the live updated plot.

``````from matplotlib.widgets import Slider

midax = plt.axes([0.1, 0.04, 0.2, 0.03], facecolor="lightblue")
s1ax = plt.axes([0.4, 0.04, 0.2, 0.03], facecolor="lightblue")
s2ax = plt.axes([0.7, 0.04, 0.2, 0.03], facecolor="lightblue")

mid = Slider(midax, 'Midpoint', x[0], x[-1], valinit=0)
s1 = Slider(s1ax, 'S1', 0.5, 6, valinit=1.7)
s2 = Slider(s2ax, 'S2', 0.5, 6, valinit=4)

def update(val):
norm=SqueezedNorm(vmin=-13, vmax=4, mid=mid.val, s1=s1.val, s2=s2.val)
im.set_norm(norm)
cbar.update_bruteforce(im)
line.set_ydata(norm(x))
fig.canvas.draw_idle()

mid.on_changed(update)
s1.on_changed(update)
s2.on_changed(update)

``````

You can use a custom `normalizer`. Conveniently, the example for this in the docs is already an 'alternative midpoint' normalizer. The example is made by Joe Kington, so all credits to him.

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

Custom normalize class:

``````class MidpointNormalize(mpl.colors.Normalize):
## class from the mpl docs:
# https://matplotlib.org/users/colormapnorms.html

def __init__(self, vmin=None, vmax=None, midpoint=None, clip=False):
self.midpoint = midpoint
super().__init__(vmin, vmax, clip)

def __call__(self, value, clip=None):
# I'm ignoring masked values and all kinds of edge cases to make a
# simple example...
x, y = [self.vmin, self.midpoint, self.vmax], [0, 0.5, 1]
``````

The result:

``````data = np.linspace(-5,1,100)[None,:]

fig, axs = plt.subplots(2,1, figsize=(5,2), facecolor='w', subplot_kw=dict(xticks=[], yticks=[]))

props = dict(aspect=15, cmap=plt.cm.coolwarm)

axs[0].imshow(data, **props)
axs[1].imshow(data, norm=MidpointNormalize(midpoint=0), **props)
``````

This is a relative simple example, but more complex scalings can be achieved in a similar matter.