I am trying to create a heat map with python. For this I have to assign an RGB value to every value in the range of possible values. I thought of changing the color from blue (minimal value) over green to red (maximal value).

The picture example below explains how I thought of the color composition: We have a range from 1 (pure blue) to 3 (pure red), 2 is in between resembled by green.

color composition RGB in range(1-3)

I read about linear interpolation and wrote a function that (more or less) handles the calculation for a certain value in the range between a minimum and a maximum and returns an RGB tuple. It uses if and elif conditions (which does not make me completely happy):

def convert_to_rgb(minimum, maximum, value):
    minimum, maximum = float(minimum), float(maximum)    
    halfmax = (minimum + maximum) / 2
    if minimum <= value <= halfmax:
        r = 0
        g = int( 255./(halfmax - minimum) * (value - minimum))
        b = int( 255. + -255./(halfmax - minimum)  * (value - minimum))
        return (r,g,b)    
    elif halfmax < value <= maximum:
        r = int( 255./(maximum - halfmax) * (value - halfmax))
        g = int( 255. + -255./(maximum - halfmax)  * (value - halfmax))
        b = 0
        return (r,g,b)

However I wonder if one could write a function for each color value without using if conditions. Does anybody have an idea? Thank you a lot!

def rgb(minimum, maximum, value):
    minimum, maximum = float(minimum), float(maximum)
    ratio = 2 * (value-minimum) / (maximum - minimum)
    b = int(max(0, 255*(1 - ratio)))
    r = int(max(0, 255*(ratio - 1)))
    g = 255 - b - r
    return r, g, b
  • 1
    halfmax should be calculated as (minimum - maximum) / 2 and value/halfmax should be (value - minimum)/halfmax, otherwise it only works properly when minimum is 1 and maximum is 3. See: codereview.stackexchange.com/a/64720/7641 – Guffa Oct 4 '14 at 18:55
  • @guffa Thanks for catching that! Answer updated. – John1024 Oct 4 '14 at 19:22

Here's another way to do it that, while not as absolutely short as possible, is much more general since it hasn't been hardcoded for your specific set of colors. This means it can also be used to linearly interpolate a specified range of values over a variably-sized palette of arbitrary colors.

Also note that colors could have been interpolated in other colorspaces giving results that may be more pleasing than in others. This is illustrated in the different results obtained from the two separate answers I submitted to a related question titled Range values to pseudocolor.

import sys
EPSILON = sys.float_info.epsilon  # Smallest possible difference.

def convert_to_rgb(minval, maxval, val, colors):
    # "colors" is a series of RGB colors delineating a series of
    # adjacent linear color gradients between each pair.
    # Determine where the given value falls proportionality within
    # the range from minval->maxval and scale that fractional value
    # by the total number in the "colors" pallette.
    i_f = float(val-minval) / float(maxval-minval) * (len(colors)-1)
    # Determine the lower index of the pair of color indices this
    # value corresponds and its fractional distance between the lower
    # and the upper colors.
    i, f = int(i_f // 1), i_f % 1  # Split into whole & fractional parts.
    # Does it fall exactly on one of the color points?
    if f < EPSILON:
        return colors[i]
    else:  # Otherwise return a color within the range between them.
        (r1, g1, b1), (r2, g2, b2) = colors[i], colors[i+1]
        return int(r1 + f*(r2-r1)), int(g1 + f*(g2-g1)), int(b1 + f*(b2-b1))

if __name__ == '__main__':
    minval, maxval = 1, 3
    steps = 10
    delta = float(maxval-minval) / steps
    colors = [(0, 0, 255), (0, 255, 0), (255, 0, 0)]  # [BLUE, GREEN, RED]
    print('  Val       R    G    B')
    for i in range(steps+1):
        val = minval + i*delta
        r, g, b = convert_to_rgb(minval, maxval, val, colors)
        print('{:.3f} -> ({:3d}, {:3d}, {:3d})'.format(val, r, g, b))

Numeric output:

  Val       R    G    B
1.000 -> (  0,   0, 255)
1.200 -> (  0,  50, 204)
1.400 -> (  0, 101, 153)
1.600 -> (  0, 153, 101)
1.800 -> (  0, 204,  50)
2.000 -> (  0, 255,   0)
2.200 -> ( 51, 203,   0)
2.400 -> (102, 152,   0)
2.600 -> (153, 101,   0)
2.800 -> (203,  51,   0)
3.000 -> (255,   0,   0)

Here's the output visualized as a horizontal gradient:

horizontal gradient generated with function in answer

  • I've used this code, and it works delightfully, even with very different color maps (red, orange, white). This solution could be improved with comments in your code helping us understand the theory and practice here. For instance, what is the point of finding the difference between the float and the int above? – Wes Modes Aug 18 '18 at 17:02
  • One way to view this is that colors specify a line through a 2D color space upon which the linear input is mapped. – Wes Modes Aug 18 '18 at 17:41
  • @Wes: The subtraction is one of the steps involved in the process of separating the integer and fractional portions of the floating point result of the first linear interpolation (aka lerp) that's being done. The integer part is i and the fractional part is f. These two values are then used to do yet another lerp to compute the weighted average between colors[i] and colors[i+1] in the palette (using f, which will lie within the range of 0–1.0). It's a technique I dreamed up years ago for making smooth gradients. – martineau Aug 18 '18 at 21:04
  • @Wes: One thing wrong with that view of what's going on is that most colorspaces are 3D (e.g. RGB, YIQ, and HLS), not 2D. – martineau Aug 18 '18 at 21:14
  • True. A line through 3D color space. – Wes Modes Aug 18 '18 at 21:31

You can often eliminate an if with an index into an array of two values. Python lacks a ternary conditional operator, but this works:

r = [red_curve_1, red_curve_2][value>=halfmax]
g = [green_curve_1, green_curve_2][value>=halfmax]
b = [blue_curve_1, blue_curve_2][value>=halfmax]

Replace the *_curve_1 and *_curve_2 expressions with the constants or slopes or curves either left or right of the midpoint, respectively.

I'll leave those substitutions to you, but for example:

  • red_curve_1 and blue_curve_2 are simply 0
  • green_curve_1 is 255*(value-minimum)/(halfmax-minimum)
  • etc.
  • This is just what I would call "conditional indexing". BTW, Python does have a ternary operator which it calls a Conditional Expression. It allows statements like r = red_curve_1 if value >= halfmax else red_curve_2 -- although I suppose using it would make it even more obvious that the approach really wasn't getting rid the if conditions the OP seeks to eliminate. – martineau Dec 28 '13 at 19:23
  • Thanks for the reminder about the conditional expression. It actually reads less obscurely than the conditional indexing I proposed. But as you say, OP apparently wants to get rid of if. (The conditional expression approach also has the advantage of not evaluating everything before returning its result.) – Darren Stone Dec 28 '13 at 19:30

"We sense light intensity on a logarithmic scale – an exponential intensity ramp will be seen as a linear ramp" https://courses.cs.washington.edu/courses/cse455/09wi/Lects/lect11.pdf

From the https://en.wikipedia.org/wiki/RGB_color_model: "an input intensity RGB value of (0.5, 0.5, 0.5) only outputs about 22% of full brightness (1.0, 1.0, 1.0), instead of 50%"

This leads to the brownish smudge at 2.5 in @martineau example, where it should be yellow, and cyan at 1.5 in order to get a proper hue gradient.

So the formula you should use to get the gradient is not necessarily what you will want. (sorry for not answering your question directly)

But it might be handy to convert to the HSV or HLS color space model, and use H (for hue) and use that as input, and convert back to RGB for display purposes. ie:

colorsys.hsv_to_rgb(value, 1, 1)


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.