Wiem, że to późna pora na grę, ale właśnie przeszedłem przez ten proces i wymyśliłem rozwiązanie, które być może jest mniej niezawodne niż normalizacja podklas, ale znacznie prostsze. Pomyślałem, że dobrze byłoby podzielić się tym tutaj dla potomności.
Funkcja
import numpy as np
import matplotlib
import matplotlib.pyplot as plt
from mpl_toolkits.axes_grid1 import AxesGrid
def shiftedColorMap(cmap, start=0, midpoint=0.5, stop=1.0, name='shiftedcmap'):
'''
Function to offset the "center" of a colormap. Useful for
data with a negative min and positive max and you want the
middle of the colormap's dynamic range to be at zero.
Input
-----
cmap : The matplotlib colormap to be altered
start : Offset from lowest point in the colormap's range.
Defaults to 0.0 (no lower offset). Should be between
0.0 and `midpoint`.
midpoint : The new center of the colormap. Defaults to
0.5 (no shift). Should be between 0.0 and 1.0. In
general, this should be 1 - vmax / (vmax + abs(vmin))
For example if your data range from -15.0 to +5.0 and
you want the center of the colormap at 0.0, `midpoint`
should be set to 1 - 5/(5 + 15)) or 0.75
stop : Offset from highest point in the colormap's range.
Defaults to 1.0 (no upper offset). Should be between
`midpoint` and 1.0.
'''
cdict = {
'red': [],
'green': [],
'blue': [],
'alpha': []
}
reg_index = np.linspace(start, stop, 257)
shift_index = np.hstack([
np.linspace(0.0, midpoint, 128, endpoint=False),
np.linspace(midpoint, 1.0, 129, endpoint=True)
])
for ri, si in zip(reg_index, shift_index):
r, g, b, a = cmap(ri)
cdict['red'].append((si, r, r))
cdict['green'].append((si, g, g))
cdict['blue'].append((si, b, b))
cdict['alpha'].append((si, a, a))
newcmap = matplotlib.colors.LinearSegmentedColormap(name, cdict)
plt.register_cmap(cmap=newcmap)
return newcmap
Przykład
biased_data = np.random.random_integers(low=-15, high=5, size=(37,37))
orig_cmap = matplotlib.cm.coolwarm
shifted_cmap = shiftedColorMap(orig_cmap, midpoint=0.75, name='shifted')
shrunk_cmap = shiftedColorMap(orig_cmap, start=0.15, midpoint=0.75, stop=0.85, name='shrunk')
fig = plt.figure(figsize=(6,6))
grid = AxesGrid(fig, 111, nrows_ncols=(2, 2), axes_pad=0.5,
label_mode="1", share_all=True,
cbar_location="right", cbar_mode="each",
cbar_size="7%", cbar_pad="2%")
im0 = grid[0].imshow(biased_data, interpolation="none", cmap=orig_cmap)
grid.cbar_axes[0].colorbar(im0)
grid[0].set_title('Default behavior (hard to see bias)', fontsize=8)
im1 = grid[1].imshow(biased_data, interpolation="none", cmap=orig_cmap, vmax=15, vmin=-15)
grid.cbar_axes[1].colorbar(im1)
grid[1].set_title('Centered zero manually,\nbut lost upper end of dynamic range', fontsize=8)
im2 = grid[2].imshow(biased_data, interpolation="none", cmap=shifted_cmap)
grid.cbar_axes[2].colorbar(im2)
grid[2].set_title('Recentered cmap with function', fontsize=8)
im3 = grid[3].imshow(biased_data, interpolation="none", cmap=shrunk_cmap)
grid.cbar_axes[3].colorbar(im3)
grid[3].set_title('Recentered cmap with function\nand shrunk range', fontsize=8)
for ax in grid:
ax.set_yticks([])
ax.set_xticks([])
Wyniki przykładu: