"Histogram Equalization is the process of obtaining transformation function automatically. So you need not have to worry about shape and nature of transformation function"
So in Histogram equalization, transformation function is calculated using cumulative frequency approach and this process is automatic. From the histogram of the image, we determine the cumulative histogram,
c, rescaling the values as we go so that they occupy an 8-bit range. In this way,
c becomes a look-up table that can be subsequently applied to the image in order to carry out equalization.
rk nk c sk = c/MN (L-1)sk rounded value
0 800 800 0.195 1.365 1
1 520 1320 0.322 2.254 2
2 970 2290 0.559 3.913 4
3 660 2950 0.720 5.04 5
4 330 3280 0.801 5.601 6
5 450 3730 0.911 6.377 6
6 260 3990 0.974 6.818 7
7 106 4096 1.000 7.0 7
Now the equalized histogram is therefore
6 330 + 450 = 780
7 260 + 106 = 366
The algorithm for equalization can be given as
Compute a scaling factor, α= 255 / number of pixels
Calculate histogram of the image
Create a look up table c with
c = α * histogram
for all remaining grey levels, i, do
c[i] = c[i-1] + α * histogram[i]
for all pixel coordinates, x and y, do
g(x, y) = c[f(x, y)]
But there is a problem with histogram equalization and that is mainly because it is a completely automatic technique, with no parameters to set. At times, it can improve our ability
to interpret an image dramatically. However, it is difficult to predict how beneficial equalization will be for any given image; in fact, it may not be of any use at all. This is because the improvement in contrast is optimal statistically, rather than perceptually. In images with narrow histograms and relatively few grey levels, a massive increase in contrast due to histogram equalisation can have the adverse effect of reducing perceived image qual-ity. In particular, sampling or quantisation artefacts and image noise may become more prominent.
The alternative to obtaining the transformation (mapping) function automatically is Histogram Specification. In histogram specification instead of requiring a flat
histogram, we specify a particular shape explicitly. We might wish to do this in cases where it is desirable for a set of related images to have the same histogram- in order, perhaps, that a particular operation produces the same results for all images.
Histogram specification can be visualised as a two-stage process. First, we transform
the input image by equalisation into a temporary image with a flat histogram. Then we
transform this equalised, temporary image into an output image possessing the desired
histogram. The mapping function for the second stage is easily obtained. Since a rescaled
version of the cumulative histogram can be used to transform a histogram with any shape
into a flat histogram, it follows that the inverse of the cumulative histogram will perform
the inverse transformation from a fiat histogram to one with a specified shape.
For more details about histogram equalization and mapping functions with C and C++ code