Algorithm to convert any positive integer to an RGB value

We have a heatmap we want to display. The numbers that will make up the values being displayed are unknown (except that they will be positive integers). The range of numbers is also unknown (again, except that they will be posiitive integars). The range could be between 0 and 200 or 578 and 1M or whatever. It depends on the data, which is unknown.

We want to take an unknown range of positive integers and turn it into a scaled (compressed) range to be displayed with RGB values in a heatmap. I hope this makes sense. Thanks!

I want to clarify that the min/max values need to be "plugged" into the forumla.

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You need to first find the range of those values to get the min and max. Then you need to create a colour scale like the bar below this image. You can experiment with different functions to map an integer to an RGB. You need 3 functions R(X), G(X), B(X). Looking at the image below it loks like B(X) peaks in the middle, R(X) peaks at the end and green is somewhere else. As long as you make sure that you never get two (RGBs) for some value of X then you've got your conversion.

EDIT: Come to think of it you could sample some unit circle around YUV space.

EDIT 2: I was just faced with color bar generation and remembered the MATLAB/Octave colorbar code. I plotted their data and got the following image.

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I would add that creating the color bar will be done most easily in the HSV space –  daveb Mar 3 '10 at 21:17
I like this idea . . . but since we won't know the min/max until we pull the data to populate the heatmap, how do we create the color bar values dynamically? The min/max values have to be part of the algoritm/formula . . . –  Richard Mar 3 '10 at 23:19
@Richard: In that case you'd have to redraw the colour display every time a new data came in that was out of the original range. The R(X), G(X), B(X) functions could take normalized X values, and you just need to updated the normalization function when higher values come in. This would cause all colors to appear to get cooler as higher values came in. I don't see a way around this without knowing the range ahead of time. –  Chris H Mar 4 '10 at 0:57
Yes we will redraw the colour display every time. My question is, how do I normalize these colors? And how do I do it in a logaritmic or exponential way, i.e. if the range of values is huge (for instance between 200 and 10,000,000), how do we still represent that 200. Especially if most of the values fall closer to the 200. Somehow it has to be weighted toward the end of the spectrum where most of the values are . . . –  Richard Mar 4 '10 at 1:45
On the other hand, if it is fairly even, for instance 200, 500k, 1M, then the distribution should be even as well . .. –  Richard Mar 4 '10 at 1:46

Without knowing the range of values, there isn't much you can do to come up with a meaningful function mapping an arbitrary range of positive integers to a heat-map type range of colors.

I think you're going to have to run through your data at least once to get the min/max or know them ahead of time. Once you have that you can normalize appropriately and use any number of color schemes. The simplest solution would be to specify something like "hue" and convert from HSV to RGB.

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There are no mathematical formula's or algorithms that can normalize a set of data using the min/max values as inputs? We need some logarithmic function I think, or something to that effect. We don't want some values lost in the heatmap because they are so different from other values. For example, if we had a value 20 and a value 1M, we want both to be represented, not for the 20 to appear as 0. –  Richard Mar 3 '10 at 23:21
Then look at either a log distribution or histogram equilisation –  Martin Beckett Mar 3 '10 at 23:32
That is getting beyond me im afraid . . . –  Richard Mar 4 '10 at 2:00

Simple algorithm

``````// given a max and min value
float red,green,blue;
float range=max-min;
float mid=(max+min)/2.0;

//foreach value
red = (value[ii]-mid)/range;
if (red>0.0) {
//above mid = red-green
blue=0.0;
green = 1.0-red;
} else {
// lower half green-blue
blue=-red;
green = 1.0-blue;
red=0.0;
}

}
``````

More complex:
If your range is a few million but most are around 0 you want to scale it so that 'red' in the above example is the log of the distance from the midpoint. The cod eis a little more complicated if the values are +/-

``````// assume equally distributed around 0 so max is the largest (or most negative number)
float range = log(fabs(max));
float mid=0.0

// foreach value
if (value[ii] > 0.0 ) {
// above mid = red-green
red = log(value[ii])/range;
blue=0.0;
green = 1.0 - red;
} else {
// below mid = green-blue
blue=-log(value[ii])/range;
green = 1.0 - blue;
red = 0.0;
}
``````

note - I haven't tested this code, just spinning ideas!

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Martin, I just tried that in excel . . . no luck. The rgb values are all around .5 or 0, expecially with big difference in values. –  Richard Mar 4 '10 at 0:04
Yes - it was meant for the simple case, just a brain dump for the search engines. If all your values are around 0.5 with outliers can you simply take the log of value-mid ? –  Martin Beckett Mar 4 '10 at 0:08
Not sure what you mean just a brain dump for the search engines . . . I don't think that will work. Some of the red values are negative, so the log doesn't work there. We really need a logarithmic compression of the numbers in the range. –  Richard Mar 4 '10 at 0:17
Sorry - meant that i posted the simple algorithm here so i could point people to it, or they would find it in search. –  Martin Beckett Mar 4 '10 at 0:19

man, you could probably use YUV color space and only for demonstration purposes convert it to RGB.

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You want to convert your data values to a frequency of light:

• lower wavelength = cooler colors = blueish
• higher wavelength = warmer colors = redder

The frequencies of visible light go from about 350nm (violet) to 650nm (red):

The following function converts numbers in your specified range to the the range of visible light, then gets the rgb:

``````function DataPointToColor(Value, MinValue, MaxValue: Real): TColor;
var
r, g, b: Byte;
WaveLength: Real;
begin
WaveLength := GetWaveLengthFromDataPoint(Value, MinValue, MaxValue);
WavelengthToRGB(Wavelength, r, g, b);
Result := RGB(r, g, b);
end;
``````

With the function i wrote off the top of my head:

``````function GetWaveLengthFromDataPoint(Value: Real; MinValues, MaxValues: Real): Real;
const
MinVisibleWaveLength = 350.0;
MaxVisibleWaveLength = 650.0;
begin
//Convert data value in the range of MinValues..MaxValues to the
//range 350..650

Result := (Value - MinValue) / (MaxValues-MinValues) *
(MaxVisibleWavelength - MinVisibleWavelength) +
MinVisibleWaveLength;
end;
``````

And a function i found on the internets, that converts a wavelength into RGB:

``````PROCEDURE WavelengthToRGB(CONST Wavelength:  Nanometers;
VAR R,G,B:  BYTE);
CONST
Gamma        =   0.80;
IntensityMax = 255;
VAR
Blue   :  DOUBLE;
factor :  DOUBLE;
Green  :  DOUBLE;
Red    :  DOUBLE;
FUNCTION Adjust(CONST Color, Factor:  DOUBLE):  INTEGER;
BEGIN
IF   Color = 0.0
THEN RESULT := 0     // Don't want 0^x = 1 for x <> 0
ELSE RESULT := ROUND(IntensityMax * Power(Color * Factor, Gamma))
BEGIN
CASE TRUNC(Wavelength) OF
380..439:
BEGIN
Red   := -(Wavelength - 440) / (440 - 380);
Green := 0.0;
Blue  := 1.0
END;
440..489:
BEGIN
Red   := 0.0;
Green := (Wavelength - 440) / (490 - 440);
Blue  := 1.0
END;
490..509:
BEGIN
Red   := 0.0;
Green := 1.0;
Blue  := -(Wavelength - 510) / (510 - 490)
END;
510..579:
BEGIN
Red   := (Wavelength - 510) / (580 - 510);
Green := 1.0;
Blue  := 0.0
END;
580..644:
BEGIN
Red   := 1.0;
Green := -(Wavelength - 645) / (645 - 580);
Blue  := 0.0
END;
645..780:
BEGIN
Red   := 1.0;
Green := 0.0;
Blue  := 0.0
END;
ELSE
Red   := 0.0;
Green := 0.0;
Blue  := 0.0
END;
// Let the intensity fall off near the vision limits
CASE TRUNC(Wavelength) OF
380..419:  factor := 0.3 + 0.7*(Wavelength - 380) / (420 - 380);
420..700:  factor := 1.0;
701..780:  factor := 0.3 + 0.7*(780 - Wavelength) / (780 - 700)
ELSE       factor := 0.0
END;
END {WavelengthToRGB};
``````

Sample use:

Data set in the range of 10..65,000,000. And this particular data point has a value of 638,328:

``````color = DataPointToColor(638328, 10, 65000000);
``````
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That's a great idea. The only problem is that the conversion to the wavelength has to be unevenly compressed. i.e. if the range of values is huge, we don't want decimal values for the smaller values. They still need to be represented. –  Richard Mar 4 '10 at 1:43
@Richard: You have to decide what is uneven. e.g. if the entire world is in a deep freeze, except for one town in Angola, which is too hot to live in: then everything should be blue, except for that one dot which should be red. Unless of course you want to exaggerate values in the lower range. You're going to have to decide what kind of lying you want to perform, in order to best represent your data. If the source data isn't linear (as you suggest), then a common trick is to use a log scale; apply a natural log ln(value) to the values before plotting them. –  Ian Boyd Mar 4 '10 at 15:05

Continuing from Ian Boyd's excellent answer, I needed a distinguishable set of colours to build a heatmap. The trick was to find a way to differentiate close colours and I found a solution by converting to HSV and varying the V according to the value, with a little emphasis in the middle of the colour range to bring out the yellows and oranges.

Here's the code:

``````Imports System.Drawing
Imports RGBHSV

Module HeatToColour_

' Thanks to Ian Boyd's excellent post here:
' http://stackoverflow.com/questions/2374959/algorithm-to-convert-any-positive-integer-to-an-rgb-value

Private Const MinVisibleWaveLength As Double = 450.0
Private Const MaxVisibleWaveLength As Double = 700.0
Private Const Gamma As Double = 0.8
Private Const IntensityMax As Integer = 255

Function HeatToColour(ByVal value As Double, ByVal MinValue As Double, ByVal MaxValues As Double) As System.Drawing.Color

Dim wavelength As Double
Dim Red As Double
Dim Green As Double
Dim Blue As Double
Dim Factor As Double
Dim scaled As Double

scaled = (value - MinValue) / (MaxValues - MinValue)

wavelength = scaled * (MaxVisibleWaveLength - MinVisibleWaveLength) + MinVisibleWaveLength

Select Case Math.Floor(wavelength)

Case 380 To 439
Red = -(wavelength - 440) / (440 - 380)
Green = 0.0
Blue = 1.0

Case 440 To 489
Red = 0.0
Green = (wavelength - 440) / (490 - 440)
Blue = 1.0

Case 490 To 509
Red = 0.0
Green = 1.0
Blue = -(wavelength - 510) / (510 - 490)

Case 510 To 579
Red = (wavelength - 510) / (580 - 510)
Green = 1.0
Blue = 0.0

Case 580 To 644
Red = 1.0
Green = -(wavelength - 645) / (645 - 580)
Blue = 0.0

Case 645 To 780
Red = 1.0
Green = 0.0
Blue = 0.0

Case Else
Red = 0.0
Green = 0.0
Blue = 0.0

End Select

' Let the intensity fall off near the vision limits
Select Case Math.Floor(wavelength)
Case 380 To 419
Factor = 0.3 + 0.7 * (wavelength - 380) / (420 - 380)
Case 420 To 700
Factor = 1.0
Case 701 To 780
Factor = 0.3 + 0.7 * (780 - wavelength) / (780 - 700)
Case Else
Factor = 0.0
End Select

Dim R As Integer = Adjust(Red, Factor)
Dim G As Integer = Adjust(Green, Factor)
Dim B As Integer = Adjust(Blue, Factor)

Dim result As Color = System.Drawing.Color.FromArgb(255, R, G, B)
Dim resulthsv As New HSV
resulthsv = ColorToHSV(result)
resulthsv.Value = 0.7 + 0.1 * scaled + 0.2 * Math.Sin(scaled * Math.PI)

result = HSVToColour(resulthsv)

Return result

End Function
Private Function Adjust(ByVal Colour As Double, ByVal Factor As Double) As Integer
If Colour = 0 Then
Return 0
Else
Return Math.Round(IntensityMax * Math.Pow(Colour * Factor, Gamma))
End If
End Function

End Module

Imports System.Drawing
Public Module RGBHSV

Public Class HSV
Sub New()
Hue = 0
Saturation = 0
Value = 0
End Sub
Public Sub New(ByVal H As Double, ByVal S As Double, ByVal V As Double)
Hue = H
Saturation = S
Value = V
End Sub
Public Hue As Double
Public Saturation As Double
Public Value As Double
End Class

Public Function ColorToHSV(ByVal color As Color) As HSV
Dim max As Integer = Math.Max(color.R, Math.Max(color.G, color.B))
Dim min As Integer = Math.Min(color.R, Math.Min(color.G, color.B))
Dim result As New HSV
With result
.Hue = color.GetHue()
.Saturation = If((max = 0), 0, 1.0 - (1.0 * min / max))
.Value = max / 255.0
End With
Return result
End Function

Public Function HSVToColour(ByVal hsv As HSV) As Color
Dim hi As Integer
Dim f As Double

With hsv
hi = Convert.ToInt32(Math.Floor(.Hue / 60)) Mod 6
f = .Hue / 60 - Math.Floor(.Hue / 60)
.Value = .Value * 255
Dim v As Integer = Convert.ToInt32(.Value)
Dim p As Integer = Convert.ToInt32(.Value * (1 - .Saturation))
Dim q As Integer = Convert.ToInt32(.Value * (1 - f * .Saturation))
Dim t As Integer = Convert.ToInt32(.Value * (1 - (1 - f) * .Saturation))

If hi = 0 Then
Return Color.FromArgb(255, v, t, p)
ElseIf hi = 1 Then
Return Color.FromArgb(255, q, v, p)
ElseIf hi = 2 Then
Return Color.FromArgb(255, p, v, t)
ElseIf hi = 3 Then
Return Color.FromArgb(255, p, q, v)
ElseIf hi = 4 Then
Return Color.FromArgb(255, t, p, v)
Else
Return Color.FromArgb(255, v, p, q)
End If
End With
End Function

End Module
``````

and a resulting heatmap, showing GDP per capita for the countries in the EEC:

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A little late, but I was trying to do the same and found I can modify HSV to RGB to get a similar result. It's similar to the wavelength approach but by passes the need to convert to wavelength first. Just substitute H with your value (assuming a value between 0 and 1), and fix S and V to 1. I found the HSVtoRGB example here to be very helpful:

http://www.cs.rit.edu/~ncs/color/t_convert.html

However, I had to change the lines

``````h /= 60;
i = floor ( h );
``````

to

``````h *= 5;
i = (int) h;
``````

to get an output that goes through the whole spectrum.

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Function for colorbar

``````// value between 0 and 1 (percent)
function color(value) {
var RGB = {R:0,G:0,B:0};

// y = mx + b
// m = 4
// x = value
// y = RGB._
if (0 <= value && value <= 1/8) {
RGB.R = 0;
RGB.G = 0;
RGB.B = 4*value + .5; // .5 - 1 // b = 1/2
} else if (1/8 < value && value <= 3/8) {
RGB.R = 0;
RGB.G = 4*value - .5; // 0 - 1 // b = - 1/2
RGB.B = 0;
} else if (3/8 < value && value <= 5/8) {
RGB.R = 4*value - 1.5; // 0 - 1 // b = - 3/2
RGB.G = 1;
RGB.B = -4*value + 2.5; // 1 - 0 // b = 5/2
} else if (5/8 < value && value <= 7/8) {
RGB.R = 1;
RGB.G = -4*value + 3.5; // 1 - 0 // b = 7/2
RGB.B = 0;
} else if (7/8 < value && value <= 1) {
RGB.R = -4*value + 4.5; // 1 - .5 // b = 9/2
RGB.G = 0;
RGB.B = 0;
} else {    // should never happen - value > 1
RGB.R = .5;
RGB.G = 0;
RGB.B = 0;
}

// scale for hex conversion
RGB.R *= 15;
RGB.G *= 15;
RGB.B *= 15;

return Math.round(RGB.R).toString(16)+''+Math.round(RGB.G).toString(16)+''+Math.round(RGB.B).toString(16);
}
``````
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This answer is probably a little late to the party. I'm displaying some environmental data, and need to colour the resulting bars from green to red relative to the max and min of the data set (or which ever values are passed as max and min to the function. Anyway, the below accomplishes that. Can be changed for blue to red fairly easily enough, I would think.

``````// scale colour temp relatively

function getColourTemp(maxVal, minVal, actual) {
var midVal = (maxVal - minVal)/2;
var intR;
var intG;
var intB = Math.round(0);

if (actual >= midVal){
intR = 255;
intG = Math.round(255 * ((maxVal - actual) / (maxVal - midVal)));
}
else{
intG = 255;
intR = Math.round(255 * ((actual - minVal) / (midVal - minVal)));
}

}
``````
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