# Interpolate from one color to another

I am trying to get an interpolation of one color to another shade of the same color. (for eg: sky blue to dark blue and then back).

I stumbled upon some code that could be used if the range was from 0-255 or 0-1. However, in my case, I have the RGB codes for Color1 and Color2, and want the rotation to occur.

Color 1: 151,206,255
Color 2: 114,127,157

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Normally you would do the interpolation in another colour space, e.g. HSV, and convert the interpolated HSV values back to RGB. –  Paul R Nov 21 '12 at 8:19
Your color codes seems to be RGB... –  Synxis Nov 21 '12 at 8:20
@PaulR: Why is that we won't use RGB in interpolation? –  user1240679 Nov 21 '12 at 8:21
@Synxis: These are RGB in fact and I was thinking of interpolation in RGB terms. Didn't know about HSV stuff ;/ –  user1240679 Nov 21 '12 at 8:23
The HSV colour space corresponds much more closely to colour as it is perceived by humans - if you want a "natural" interpolation between two colours you therefore want to use a colour space that varies in an appropriate way - e.g. you don't want the perceived brightness to change as you interpolate. –  Paul R Nov 21 '12 at 8:25

I suggest you convert RGB to HSV, then adjust its components, then convert back to RGB.

Wikipedia has an article about it, and it's been discussed here before:

HSL to RGB color conversion

Algorithm to convert RGB to HSV and HSV to RGB?

Also many frameworks have conversion functions, for example Qt has QColor class.

But the question was about the actual interpolation... here's a trivial interpolation function:

``````// 0 <= stepNumber <= lastStepNumber
int interpolate(int startValue, int endValue, int stepNumber, int lastStepNumber)
{
return (endValue - startValue) * stepNumber / lastStepNumber + startValue;
}
``````

So call that for all color components you want to interpolate, in a loop. With RBG interpolation, you need to interpolate every component, in some other color space you may need to interpolate just one.

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And the interpolation ? –  user1240679 Nov 21 '12 at 8:25
If you want an example loop, you could add some more info to the question, like how do you get the colors, what the color struct/class looks like, and where do you want to put the results (series of colors). –  hyde Nov 21 '12 at 8:54
HSV is only an improvement over RGB if the hue values are widely separated. –  Mark Ransom Apr 24 at 16:13

Convert your RGB colors to HSV then interpolate each component (not only the color, see end of answer), afterwards you can convert back to RGB.

You can do RGB interpolation, but the results are better with HSV, because in this space color is separated from luminance and saturation (Wikipedia article on HSV). HSV interpolation is more "logical" than the RGB one, because with the latter you can get extra colors while interpolating.

Some code for interpolation:

``````template<typename F>
ColorRGB interpolate(ColorRGB a, ColorRGB, b, float t, F interpolator)
{
// 0.0 <= t <= 1.0
ColorHSV ca = convertRGB2HSV(a);
ColorHSV cb = convertRGB2HSV(b);
ColorHSV final;

final.h = interpolator(ca.h, cb.h, t);
final.s = interpolator(ca.s, cb.s, t);
final.v = interpolator(ca.v, cb.v, t);

return convertHSV2RGB(final);
}

int linear(int a, int b, float t)
{
return a * (1 - t) + b * t;
}

// use: result = interpolate(color1,color2,ratio,&linear);
``````
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I know this is little bit old, but is worthy if someone is searching for it.

First of all, you can do interpolation in any color space, including RGB, which, in my opinion, is one of the easiest.

Let's assume the variation will be controlled by a fraction value between 0 and 1 (e.g. 0.3), where 0 means full color1 and 1 means full color2.

The theory:

``````Result = (color2 - color1) * fraction + color1
``````

Applying:

As the RGB has 3 channels (red, green and blue) we have to perform this math for each one of the channels.

``````color1: 151,206,255
color 2: 114,127,157

R =  (114-151) * fraction + 151
G =  (127-206) * fraction + 206
B =  (157-255) * fraction + 255
``````

Simple like that!

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I see that you have tagged this question under "openframeworks" tag. so all you need to do is use the method `ofColor::getLerped` or `ofColor::lerp`

`getLerped` returns new value, while `lerp` modifies the color.

for example:

``````ofColor c1(151,206,255);
ofColor c2(114,127,157);

float p = 0.2f;
ofColor c3 = c1.getLerped(c2, p);
``````

or

``````c1.lerp(c2, 0.3f);
``````
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I have adapted Synxis's C example (above) into an executable JavaScript program.

The program interpolates the color yellow, from red and green. The input and output is in RGB-space, but the interpolation is handled in the HSV-space. I also added an RGB interpolation example. As you can see below, a dark-yellow is produced if you interpolate red and green in RGB-space.

``````/** Main */
var red        = { r : 255, g : 0,   b : 0 };
var green      = { r : 0,   g : 255, b : 0 };
var yellow     = interpolateHsv(red, green, 0.5, linear);
var darkYellow = interpolateRgb(red, green, 0.5, linear);

document.body.innerHTML =
'Yellow: '      + JSON.stringify(yellow,     null, '  ') + '<br />' +
'Dark Yellow: ' + JSON.stringify(darkYellow, null, '  ');

/**
* Returns an HSV interpolated value between two rgb values.
*
* @param {Object} rgbA - rgb() tuple
* @param {Object} rgbB - rgb() tuple
* @param {Number} threshold - float between [0.0, 1.0]
* @param {function} interpolatorFn - interpolator function
* @return {Object} rbg
*/
function interpolateHsv(rgbA, rgbB, threshold, interpolatorFn) {
var hsvA = rgbToHsv(rgbA);
var hsvB = rgbToHsv(rgbB);
threshold = toArray(threshold, 3);
return hsvToRgb({
h : interpolatorFn(hsvA.h, hsvB.h, threshold[0]),
s : interpolatorFn(hsvA.s, hsvB.s, threshold[1]),
v : interpolatorFn(hsvA.v, hsvB.v, threshold[2])
});
}

/**
* Returns an RGB interpolated value between two rgb values.
*
* @param {Object} rgbA - rgb() tuple
* @param {Object} rgbB - rgb() tuple
* @param {Number} threshold - float between [0.0, 1.0]
* @param {function} interpolatorFn - interpolator function
* @return {Object} rbg
*/
function interpolateRgb(rgbA, rgbB, threshold, interpolatorFn) {
threshold = toArray(threshold, 3);
return {
r : ~~interpolatorFn(rgbA.r, rgbB.r, threshold[0]),
g : ~~interpolatorFn(rgbA.g, rgbB.g, threshold[1]),
b : ~~interpolatorFn(rgbA.b, rgbB.b, threshold[2])
};
}

/**
* Returns an interpolated value between two values.
*
* @param {Number} valueA - color channel int value
* @param {Number} valueB - color channel int value
* @param {Number} threshold - float between [0.0, 1.0]
* @param {function} interpolatorFn - interpolator function
* @return {int}
*/
function linear(valueA, valueB, threshold) {
return valueA * (1 - threshold) + valueB * threshold;
}

/**
* Converts an RGB color value to HSV. Conversion formula
* Assumes r, g, and b are contained in the set [0, 255] and
* returns h, s, and v in the set [0, 1].
*
* @param {Object} rgb - Color in rgb mode
* @return {Object} - Color in hsv mode
*/
function rgbToHsv(rgb) {
var r = rgb.r / 255,
g = rgb.g / 255,
b = rgb.b / 255;
var max = Math.max(r, g, b), min = Math.min(r, g, b);
var h, s, v = max;
var d = max - min;
s = max === 0 ? 0 : d / max;
if (max == min) {
h = 0; // achromatic
} else {
switch(max) {
case r: h = (g - b) / d + (g < b ? 6 : 0); break;
case g: h = (b - r) / d + 2; break;
case b: h = (r - g) / d + 4; break;
}
h /= 6;
}
return {
h : h,
s : s,
v : v
};
}

/**
* Converts an HSV color value to RGB. Conversion formula
* Assumes h, s, and v are contained in the set [0, 1] and
* returns r, g, and b in the set [0, 255].
*
* @param {Object} hsv - Color in hsv mode
* @return {Object} - Color in rgb mode
*/
function hsvToRgb(hsv){
var r, g, b, i, f, p, q, t,
h = hsv.h,
s = hsv.s,
v = hsv.v;
i = Math.floor(h * 6);
f = h * 6 - i;
p = v * (1 - s);
q = v * (1 - f * s);
t = v * (1 - (1 - f) * s);
switch(i % 6){
case 0: r = v, g = t, b = p; break;
case 1: r = q, g = v, b = p; break;
case 2: r = p, g = v, b = t; break;
case 3: r = p, g = q, b = v; break;
case 4: r = t, g = p, b = v; break;
case 5: r = v, g = p, b = q; break;
}
return {
r : r * 255,
g : g * 255,
b : b * 255
};
}

function isNumeric(n) {
return !isNaN(parseFloat(n)) && isFinite(n);
}

function toArray(arr, size) {
var isNum = isNumeric(arr);
arr = !Array.isArray(arr) ? [arr] : arr;
for (var i = 1; i < size; i++) {
if (arr.length < size) {
arr.push(isNum ? arr[0] : 0);
}
}
return arr;
}``````

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