14

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:

uses two colorbars, one for magnitude and one for phase

uses a colorbar for magnitude and a circular legend for phase

uses a 2D colorbar to indicate the changes in both variables

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

16
  • 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.
    – tacaswell
    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
  • 1
    Bivariate colourmaps may also be useful for visualising such as Kaye et al. (2012) illustrates.
    – gerrit
    Oct 4, 2017 at 14:00
  • 1
    @endolith The key word in my sentence was missing. I meant to write: may be useful for visualising uncertainty such as...
    – gerrit
    Oct 4, 2017 at 14:28
  • 1
    This is what I did with it: github.com/endolith/complex_colormap
    – endolith
    Jun 10, 2019 at 16:20

4 Answers 4

9

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))

enter image description here

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

enter image description here

0
6

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.

0

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:

# read reference image
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
        self._img = plt.imread(self._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
plt.subplots_adjust(left=0.1, right=0.65)
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()

example plot

2
  • 1
    Have you seen github.com/endolith/complex_colormap?
    – endolith
    Aug 30, 2021 at 18:22
  • 1
    @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.
    – Neinstein
    Aug 30, 2021 at 19:38
0

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

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.