# Algorithm to modify brightness for RGB image?

I know there is formula for going RGB -> Luminance, but I need given a brightness parameter to modify the RGB values of an image. How do I do that?

Thanks

Map from RGB to HSL (Hue/saturation/luminance), keep the hue and saturation the same, and just modify the luminance and then do the backward mapping from HSL to RGB.

You can read more about the RGB to HSL and HSL to RGB transformations here.

The easiest way is to multiply each of the R,G,B values by some constant - if the constant is >1 it will make it brighter, and if <1 it will be darker. If you're making it brighter then you must test each value to make sure it doesn't go over the maximum (usually 255).

Not only is this simpler than the translation from RGB to HSL and back again, but it more closely approximates what happens when you shine a different amount of light at a physical object.

• Yeah, works out to the same exact thing under the model `L = (R+G+B)/3` but some models of luminance don't use that assumption (see the Wikipedia page I linked.) Since the OP was vague, I decided to be "general". – Chris A. Jun 22 '12 at 21:01
• @ChrisA. does it really work out to the same thing? I thought there was some interaction between L and S for example that does really bad things if you're making drastic changes. – Mark Ransom Jun 22 '12 at 21:03
• Good point! Precisely why I tried to assume as little as possible in my answer and leave it general. I remember learning that it does though Mark, but I'm trying to back that up now, just for curiousity's sake. – Chris A. Jun 22 '12 at 21:08
• You're right Mark, saturation has some interesting effects on RGB. My comment about `L = (R+G+B)/3` was purely mathematically motivated, but this is not how it's usually defined apparently. But your good point also is a refutation of your own answer. For isntance, try playing with a color wheel that has HSL and RGB like in mspaint. Multiplying RGB by a scalar isn't always one to one with changes is L by any means. – Chris A. Jun 22 '12 at 21:25
• Is modifying luminance by conversion to HSL and back and modifying brightness by above technique necessarily same? I mean to say, is luminance and brightness equivalent for this conversion? – nimbudew Feb 9 '15 at 6:51

My recommendation would be the same as ChrisA.'s answer, with one difference:

Use the HSP color space instead, as it is an approximation of Photoshop's algorithm and has better results.

For the sake of not just linking to HSP's site (which frankly should be more than enough; it's just that I don't like to answer without examples), here is my `C#` implementation, which follows the site's:

``````#region Definitions
//Perceived brightness to Red ratio.
private const double Pr = .299;
//Perceived brightness to Green ratio.
private const double Pg = .587;
//Perceived brightness to Blue ratio.
private const double Pb = .114;
#endregion

//Expected ranges: Hue = 0-359... Other values = 0-1
public static ColorRGB ToRGB(double hue, double saturation, double perceivedBrightness, double alpha) {
//Check values within expected range
hue = hue < 0 ? 0 : hue > 359 ? 359 : hue;
saturation = saturation < 0 ? 0 : saturation > 1 ? 1 : saturation;
perceivedBrightness = perceivedBrightness < 0 ? 0 : perceivedBrightness > 1 ? 1 : perceivedBrightness;
alpha = alpha < 0 ? 0 : alpha > 1 ? 1 : alpha;
//Conversion
var minOverMax = 1 - saturation;
double r, g, b;
if (minOverMax > 0) {
double part;
if (hue < 0.166666666666667D) { //R>G>B
hue = 6 * (hue - 0); part = 1 + hue * (1 / minOverMax - 1);
b = perceivedBrightness / Math.Sqrt(Pr / minOverMax / minOverMax + Pg * part * part + Pb);
r = b / minOverMax; g = b + hue * (r - b);
}
else if (hue < 0.333333333333333D) { //G>R>B
hue = 6 * (-hue + 0.333333333333333D); part = 1 + hue * (1 / minOverMax - 1);
b = perceivedBrightness / Math.Sqrt(Pg / minOverMax / minOverMax + Pr * part * part + Pb);
g = b / minOverMax; r = b + hue * (g - b);
}
else if (hue < 0.5D) {   //  G>B>R
hue = 6 * (hue - 0.333333333333333D); part = 1 + hue * (1 / minOverMax - 1);
r = perceivedBrightness / Math.Sqrt(Pg / minOverMax / minOverMax + Pb * part * part + Pr);
g = r / minOverMax; b = r + hue * (g - r);
}
else if (hue < 0.666666666666667D) { //B>G>R
hue = 6 * (-hue + 0.666666666666667D); part = 1 + hue * (1 / minOverMax - 1);
r = perceivedBrightness / Math.Sqrt(Pb / minOverMax / minOverMax + Pg * part * part + Pr);
b = r / minOverMax; g = r + hue * (b - r);
}
else if (hue < 0.833333333333333D) { //B>R>G
hue = 6 * (hue - 0.666666666666667D); part = 1 + hue * (1 / minOverMax - 1);
g = perceivedBrightness / Math.Sqrt(Pb / minOverMax / minOverMax + Pr * part * part + Pg);
b = g / minOverMax; r = g + hue * (b - g);
}
else { //R>B>G
hue = 6 * (-hue + 1D); part = 1 + hue * (1 / minOverMax - 1);
g = perceivedBrightness / Math.Sqrt(Pr / minOverMax / minOverMax + Pb * part * part + Pg);
r = g / minOverMax; b = g + hue * (r - g);
}
}
else {
if (hue < 0.166666666666667D) { //R>G>B
hue = 6 * (hue - 0D); r = Math.Sqrt(perceivedBrightness * perceivedBrightness / (Pr + Pg * hue * hue)); g = r * hue; b = 0;
}
else if (hue < 0.333333333333333D) { //G>R>B
hue = 6 * (-hue + 0.333333333333333D); g = Math.Sqrt(perceivedBrightness * perceivedBrightness / (Pg + Pr * hue * hue)); r = g * hue; b = 0;
}
else if (hue < 0.5D) { //G>B>R
hue = 6 * (hue - 0.333333333333333D); g = Math.Sqrt(perceivedBrightness * perceivedBrightness / (Pg + Pb * hue * hue)); b = g * hue; r = 0;
}
else if (hue < 0.666666666666667D) { //B>G>R
hue = 6 * (-hue + 0.666666666666667D); b = Math.Sqrt(perceivedBrightness * perceivedBrightness / (Pb + Pg * hue * hue)); g = b * hue; r = 0;
}
else if (hue < 0.833333333333333D) { //B>R>G
hue = 6 * (hue - 0.666666666666667D); b = Math.Sqrt(perceivedBrightness * perceivedBrightness / (Pb + Pr * hue * hue)); r = b * hue; g = 0;
}
else { //R>B>G
hue = 6 * (-hue + 1D); r = Math.Sqrt(perceivedBrightness * perceivedBrightness / (Pr + Pb * hue * hue)); b = r * hue; g = 0;
}
}
return new ColorRGB(r, g, b, alpha);
}

//Expected ranges: 0-1 on all components
public static ColorHSP FromRGB(double red, double green, double blue, double alpha) {
//Guarantee RGB values are in the correct ranges
red = red < 0 ? 0 : red > 1 ? 1 : red;
green = green < 0 ? 0 : green > 1 ? 1 : green;
blue = blue < 0 ? 0 : blue > 1 ? 1 : blue;
alpha = alpha < 0 ? 0 : alpha > 1 ? 1 : alpha;
//Prepare & cache values for conversion
var max = MathExtensions.Max(red, green, blue);
var min = MathExtensions.Min(red, green, blue);
var delta = max - min;
double h, s, p = Math.Sqrt(0.299 * red + 0.587 * green + 0.114 * blue);
//Conversion
if (delta.Equals(0)) h = 0;
else if (max.Equals(red)) {
h = (green - blue) / delta % 6;
}
else if (max.Equals(green)) h = (blue - red) / delta + 2;
else h = (red - green) / delta + 4;
h *= 60;
if (h < 0) h += 360;
if (p.Equals(0))
s = 0;
else
s = delta / p;
//Result
return new ColorHSP(h, s, p, alpha);
}
``````

Adding to Mark Ransom's Answer: It would be better to use the said factor with a 255 constant and add it to the current color-value:

``````float brightnessFac = //between -1.0 and 1.0
byte brightnessRed = red + (255f * brightnessFac);
``````

If you just do with a factor between 0.0 and 1.0

``````byte brightnessRed = red * brightnessFac;
``````

A value of 0 stays zero.

``````import java.io. * ;
import java.awt.Color;
import javax.imageio.ImageIO;
import java.io. * ;
import java.awt.image.BufferedImage;

class Psp {

public static void main(String a[]) {
try {

File input = new File("abc.jpg");
File output = new File("output1.jpg");
BufferedImage picture1 = ImageIO.read(input); // original
BufferedImage picture2 = new BufferedImage(picture1.getWidth(), picture1.getHeight(), BufferedImage.TYPE_INT_RGB);
int width = picture1.getWidth();
int height = picture1.getHeight();

int factor = 50;
for (int y = 0; y < height; y++) { //loops for images
for (int x = 0; x < width; x++) {

Color c = new Color(picture1.getRGB(x, y));
int r = c.getRed() + factor;
int b = c.getBlue() + factor;
int g = c.getGreen() + factor;

if (r >= 256) {
r = 255;
} else if (r < 0) {
r = 0;
}

if (g >= 256) {
g = 255;
} else if (g < 0) {
g = 0;
}

if (b >= 256) {
b = 255;
} else if (b < 0) {
b = 0;
}
picture2.setRGB(x, y, new Color(r, g, b).getRGB());

}
}

ImageIO.write(picture2, "jpg", output);
} catch(Exception e) {
System.out.println(e);
}

}

}
``````

Adjusting the brightness of an image is one of the easiest image processing operations that can be done. All that is involved is adding the desired change in brightness to each of the red, green and blue colour components.

it would go something like this:

``````colour = GetPixelColour(x, y)
newRed   = Truncate(Red(colour)   + brightness)
newGreen = Truncate(Green(colour) + brightness)
newBlue  = Truncate(Blue(colour)  + brightness)
PutPixelColour(x, y) = RGB(newRed, newGreen, newBlue)
``````

Code to ensures that the new values of red, green and blue are within the valid range.

``````Procedure Truncate(value)
If value < 0 Then value = 0
If value > 255 Then value = 255
Return value
EndProcedure
``````
• No, this is "weighted mixing with white" which is different than brightness. – Vortico Mar 16 '18 at 0:55