# Matlab: Creating a binned RGB histogram [duplicate]

I want to implement the following Matlab function:

``````function hist = binnedRgbHist(im, numChannelBins)
``````

Given an image `im` and a number between 1 and 256 `numChannelBins`, it should create a histogram sized `(numChannelBins)^3`.

For example, if `numChannelBins` is 2, it should produce the following 8-sized histogram:

1. Number of pixels with `R < 128, G < 128, B < 128`
2. Number of pixels with `R < 128, G < 128, B >= 128`
3. Number of pixels with `R < 128, G >= 128, B < 128`
4. Number of pixels with `R < 128, G >= 128, B >= 128`
5. Number of pixels with `R > 128, G < 128, B < 128`
6. Number of pixels with `R > 128, G < 128, B >= 128`
7. Number of pixels with `R > 128, G >= 128, B < 128`
8. Number of pixels with `R > 128, G >= 128, B >= 128`

It is like creating a cube where each axis represents one of (R,G and B), where each axis is divided into 2 bins => Finally there are 8 bins in the cube.

My questions:

• It there a built-in function for it?
• If not, how is it better to implement it in manners of runtinme using the GPU? Should I better iterate over the pixels once and create the histogram manually, or should I better iterate over the bins and each time count the number of pixels which satisfy the bin's conditions?

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• This question/answer may also be of interest. I converted each RGB tuple to a single 1D linear index, then the colour histogram becomes a 1D array instead. I also used `accumarray`, but the conversion from colour to index is what is important: stackoverflow.com/questions/25830225/… – rayryeng Nov 19 '15 at 21:07

`accumarray` is very suited for this. Let

• `im`: input image;
• `N`: number of bins per color component.

Then

``````result = accumarray(reshape(permute(ceil(im/255*N), [3 1 2]), 3, []).', 1, [N N N]);
``````

How it works

1. `ceil(im/255*N)` quantizes each color vaue to `1`, `2`, ..., `N`.
2. `reshape(permute(..., [3 1 2]), 3, []).'` transforms the quantized image into a three-column matrix where each row is a pixel and each column is a (quantized) color component.
3. `accumarray(..., 1, [N N N])` considers each row of that matrix as 3D index, and counts how many times each index appears, giving filling indices that don't appear with a `0`.

Example 1

Data:

``````>> N = 2;
>> im = randi(256,4,5,3)
im(:,:,1) =
113   152   157    65   229
138    71   215    39    41
13   108   230   160   153
142   128   125   220   214
im(:,:,2) =
208   215   182    27   230
205   161     8    95   180
225    53    73   129    31
103    97   160    83   255
im(:,:,3) =
242    29   185    89    55
202   225   156   174    96
160   197    35    87   113
244   176   146    85   120
``````

Result:

``````result(:,:,1) =
1     1
3     4
result(:,:,2) =
2     4
3     2
``````

It can be checked for example that there is only 1 pixel with all R,G,B less than 128.

Example 2

Data:

``````>> im = repmat(150,20,30,3);
>> N = 4;
``````

Result:

``````result(:,:,1) =
0     0     0     0
0     0     0     0
0     0     0     0
0     0     0     0
result(:,:,2) =
0     0     0     0
0     0     0     0
0     0     0     0
0     0     0     0
result(:,:,3) =
0     0     0     0
0     0     0     0
0     0   600     0
0     0     0     0
result(:,:,4) =
0     0     0     0
0     0     0     0
0     0     0     0
0     0     0     0
``````

In this case all pixels belong to the same 3D-bin:

I see @Luis Mendo gave a great one-liner solution as I was writing this. In case it provides some deeper intuition, my solution makes use of `histcounts` and `accumarray`:

``````im             = randi([1 255],[10,5,3]);  %// A random 10-by-5 "image"
numChannelBins = 2;

[~,~,binR]=histcounts(im(:,:,1),[1 ceil((1:numChannelBins)*(255/numChannelBins))]);
[~,~,binG]=histcounts(im(:,:,2),[1 ceil((1:numChannelBins)*(255/numChannelBins))]);
[~,~,binB]=histcounts(im(:,:,3),[1 ceil((1:numChannelBins)*(255/numChannelBins))]);
hist=accumarray([binR(:) binG(:) binB(:)],1,[numChannelBins,numChannelBins,numChannelBins])
``````

Explanation:

• the three calls to `histcounts` bin the red, green, blue pixels separately -- the third output `[~,~,binX]` of `histcounts` gives the bin index for each pixel
• `accumarray` accumulates all the unique index triplets