Is there any way to use bivariate colormaps in matplotlib?

In other words, I want to make a heatmap (or surface plot) where the color varies as a function of 2 variables. (Specifically, luminance = magnitude and hue = phase.) Is there any native way to do this? Some examples of similar plots:

Several good examples of exactly(?) what I want to do.

More examples from astronomy, but with non-perceptual hue

Edit: This is what I did with it: https://github.com/endolith/complex_colormap

• This a bit of a non-answer, but imshow will take an NxMx3 or NxMx4 array so you can do your color mapping by hand. I agree this would be useful. You might be able to get a bit of traction by sub-classing Normalize and laying out your color map very cleverly. I think the obvious extension is to let color maps take complex arguments, but that is probably a lot of work. Mar 4, 2013 at 18:02
• I'm not sure how to do this, but are you sure it's a good idea? human eye it's not very good at estimating values from color (and the jet colormap is a notorious offender). Using two at the same time can be a real brain killer. I strongly suggest you to read http://www.research.ibm.com/people/l/lloydt/color/color.HTM. Mar 15, 2013 at 0:15
• Bivariate colourmaps may also be useful for visualising such as Kaye et al. (2012) illustrates. Oct 4, 2017 at 14:00
• @endolith The key word in my sentence was missing. I meant to write: may be useful for visualising uncertainty such as... Oct 4, 2017 at 14:28
• This is what I did with it: github.com/endolith/complex_colormap Jun 10, 2019 at 16:20

imshow can take an array of [r, g, b] entries. So you can convert the absolute values to intensities and phases - to hues.

I will use as an example complex numbers, because for it it makes the most sense. If needed, you can always add numpy arrays Z = X + 1j * Y.

So for your data Z you can use e.g.

imshow(complex_array_to_rgb(Z))

where (EDIT: made it quicker and nicer thanks to this suggestion)

def complex_array_to_rgb(X, theme='dark', rmax=None):
'''Takes an array of complex number and converts it to an array of [r, g, b],
where phase gives hue and saturaton/value are given by the absolute value.
Especially for use with imshow for complex plots.'''
absmax = rmax or np.abs(X).max()
Y = np.zeros(X.shape + (3,), dtype='float')
Y[..., 0] = np.angle(X) / (2 * pi) % 1
if theme == 'light':
Y[..., 1] = np.clip(np.abs(X) / absmax, 0, 1)
Y[..., 2] = 1
elif theme == 'dark':
Y[..., 1] = 1
Y[..., 2] = np.clip(np.abs(X) / absmax, 0, 1)
Y = matplotlib.colors.hsv_to_rgb(Y)
return Y

So, for example:

Z = np.array([[3*(x + 1j*y)**3 + 1/(x + 1j*y)**2
for x in arange(-1,1,0.05)] for y in arange(-1,1,0.05)])
imshow(complex_array_to_rgb(Z, rmax=5), extent=(-1,1,-1,1))

imshow(complex_array_to_rgb(Z, rmax=5, theme='light'), extent=(-1,1,-1,1))

imshow will take an NxMx3 (rbg) or NxMx4 (grba) array so you can do your color mapping 'by hand'.

You might be able to get a bit of traction by sub-classing Normalize to map your vector to a scaler and laying out a custom color map very cleverly (but I think this will end up having to bin one of your dimensions).

I have done something like this (pdf link, see figure on page 24), but the code is in MATLAB (and buried someplace in my archives).

I agree a bi-variate color map would be useful (primarily for representing very dense vector fields where your kinda up the creek no matter what you do). I think the obvious extension is to let color maps take complex arguments. It would require specialized sub-classes of Normalize and Colormap and I am going back and forth on if I think it would be a lot of work to implement. I suspect if you get it working by hand it will just be a matter of api wrangling.

I created an easy to use 2D colormap class, that takes 2 NumPy arrays and maps them to an RGB image, based on a reference image.

I used @GjjvdBurg's answer as a starting point. With a bit of work, this could still be improved, and possibly turned into a proper Python module - if you want, feel free to do so, I grant you all credits.

TL;DR:

cmap_2d = ColorMap2D('const_chroma.jpeg', reverse_x=True)  # , xclip=(0,0.9))

# map the data x and y to the RGB space, defined by the image
rgb = cmap_2d(data_x, data_y)

# generate a colorbar image
cbar_rgb = cmap_2d.generate_cbar()

The ColorMap2D class:

class ColorMap2D:
def __init__(self, filename: str, transpose=False, reverse_x=False, reverse_y=False, xclip=None, yclip=None):
"""
Maps two 2D array to an RGB color space based on a given reference image.
Args:
filename (str): reference image to read the x-y colors from
rotate (bool): if True, transpose the reference image (swap x and y axes)
reverse_x (bool): if True, reverse the x scale on the reference
reverse_y (bool): if True, reverse the y scale on the reference
xclip (tuple): clip the image to this portion on the x scale; (0,1) is the whole image
yclip  (tuple): clip the image to this portion on the y scale; (0,1) is the whole image
"""
self._colormap_file = filename or COLORMAP_FILE
if transpose:
self._img = self._img.transpose()
if reverse_x:
self._img = self._img[::-1,:,:]
if reverse_y:
self._img = self._img[:,::-1,:]
if xclip is not None:
imin, imax = map(lambda x: int(self._img.shape[0] * x), xclip)
self._img = self._img[imin:imax,:,:]
if yclip is not None:
imin, imax = map(lambda x: int(self._img.shape[1] * x), yclip)
self._img = self._img[:,imin:imax,:]
if issubclass(self._img.dtype.type, np.integer):
self._img = self._img / 255.0

self._width = len(self._img)
self._height = len(self._img[0])

self._range_x = (0, 1)
self._range_y = (0, 1)

@staticmethod
def _scale_to_range(u: np.ndarray, u_min: float, u_max: float) -> np.ndarray:
return (u - u_min) / (u_max - u_min)

def _map_to_x(self, val: np.ndarray) -> np.ndarray:
xmin, xmax = self._range_x
val = self._scale_to_range(val, xmin, xmax)
rescaled = (val * (self._width - 1))
return rescaled.astype(int)

def _map_to_y(self, val: np.ndarray) -> np.ndarray:
ymin, ymax = self._range_y
val = self._scale_to_range(val, ymin, ymax)
rescaled = (val * (self._height - 1))
return rescaled.astype(int)

def __call__(self, val_x, val_y):
"""
Take val_x and val_y, and associate the RGB values
from the reference picture to each item. val_x and val_y
must have the same shape.
"""
if val_x.shape != val_y.shape:
raise ValueError(f'x and y array must have the same shape, but have {val_x.shape} and {val_y.shape}.')
self._range_x = (np.amin(val_x), np.amax(val_x))
self._range_y = (np.amin(val_y), np.amax(val_y))
x_indices = self._map_to_x(val_x)
y_indices = self._map_to_y(val_y)
i_xy = np.stack((x_indices, y_indices), axis=-1)
rgb = np.zeros((*val_x.shape, 3))
for indices in np.ndindex(val_x.shape):
img_indices = tuple(i_xy[indices])
rgb[indices] = self._img[img_indices]
return rgb

def generate_cbar(self, nx=100, ny=100):
"generate an image that can be used as a 2D colorbar"
x = np.linspace(0, 1, nx)
y = np.linspace(0, 1, ny)
return self.__call__(*np.meshgrid(x, y))

Usage:

Full example, using the constant chroma reference taken from here as a screenshot:

# generate data
x = y = np.linspace(-2, 2, 300)
xx, yy = np.meshgrid(x, y)
ampl = np.exp(-(xx ** 2 + yy ** 2))
phase = (xx ** 2 - yy ** 2) * 6 * np.pi
data = ampl * np.exp(1j * phase)
data_x, data_y = np.abs(data), np.angle(data)

# Here is the 2D colormap part
cmap_2d = ColorMap2D('const_chroma.jpeg', reverse_x=True)  # , xclip=(0,0.9))
rgb = cmap_2d(data_x, data_y)
cbar_rgb = cmap_2d.generate_cbar()

# plot the data
fig, plot_ax = plt.subplots(figsize=(8, 6))
plot_extent = (x.min(), x.max(), y.min(), y.max())
plot_ax.imshow(rgb, aspect='auto', extent=plot_extent,  origin='lower')
plot_ax.set_xlabel('x')
plot_ax.set_ylabel('y')
plot_ax.set_title('data')

#  create a 2D colorbar and make it fancy
bar_ax = fig.add_axes([0.68, 0.15, 0.15, 0.3])
cmap_extent = (data_x.min(), data_x.max(), data_y.min(), data_y.max())
bar_ax.imshow(cbar_rgb, extent=cmap_extent, aspect='auto',  origin='lower',)
bar_ax.set_xlabel('amplitude')
bar_ax.set_ylabel('phase')
bar_ax.yaxis.tick_right()
bar_ax.yaxis.set_label_position('right')
for item in ([bar_ax.title, bar_ax.xaxis.label, bar_ax.yaxis.label] +
bar_ax.get_xticklabels() + bar_ax.get_yticklabels()):
item.set_fontsize(7)
plt.show()

• Have you seen github.com/endolith/complex_colormap? Aug 30, 2021 at 18:22
• @endolith Not yet, cool! I missed that specific comment in the github thread. Though mine is still relevant - that one generates the colormap, mine uses a reference image, so may be more flexible. Aug 30, 2021 at 19:38

I know this is an old post, but want to help out others that may arrive late. Below is a python function to implement complex_to_rgb from sage. Note: This implementation isn't optimal, but it is readable. See links: (examples)(source code)

Code:

import numpy as np

def complex_to_rgb(z_values):

width = z_values.shape[0]
height = z_values.shape[1]
rgb = np.zeros(shape=(width, height, 3))

for i in range(width):

row = z_values[i]

for j in range(height):

# define value, real(value), imag(value)
zz = row[j]
x = np.real(zz)
y = np.imag(zz)

# define magnitued and argument
magnitude = np.hypot(x, y)
arg = np.arctan2(y, x)

# define lighness
lightness = np.arctan(np.log(np.sqrt(magnitude) + 1)) * (4 / np.pi) - 1

if lightness < 0:
bot = 0
top = 1 + lightness
else:
bot = lightness
top = 1

# define hue
hue = 3 * arg / np.pi

if hue < 0:
hue += 6

# set ihue and use it to define rgb values based on cases
ihue = int(hue)

# case 1
if ihue == 0:
r = top
g = bot + hue * (top - bot)
b = bot

# case 2
elif ihue == 1:
r = bot + (2 - hue) * (top - bot)
g = top
b = bot

# case 3
elif ihue == 2:
r = bot
g = top
b = bot + (hue - 2) * (top - bot)

# case 4
elif ihue == 3:
r = bot
g = bot + (4 - hue) * (top - bot)
b = top

# case 5
elif ihue == 4:
r = bot + (hue - 4) * (top - bot)
g = bot
b = top

# case 6
else:
r = top
g = bot
b = bot + (6 - hue) * (top - bot)

# set rgb array values
rgb[i, j, 0] = r
rgb[i, j, 1] = g
rgb[i, j, 2] = b

return rgb