I understand that the seven hu invariant moments are for translation, rotation, and scale change of the object, in order to recognize the object independently these factors.

That's why I used the function "moments" from OpenCV to extract the central moments, then I used the function HuMoments to get the seven invariant moments of the following binarized image :

enter image description here

My first question is regarding the use of the function "moments" from OpenCV. The second parameter is "binaryImage" and I set it true, because it's a binary image, is it ok?

My second doubt is regarding the output of the function "HuMoments": the seven hu invariant moments. I don't understand this data. what data is related to rotation, what for translation and what for scale change?.

Many thanks!, cheers!

  • When using geometric moments, noise pixels away from the main object (like the ones at the bottom left or top right) will give you relatively big errors in the calculation, which will propagate to the invariant calculation. – Leonidas K Jul 9 '12 at 8:35
  • Thanks Leonidas for your information. What kind of filter do you recommend me to use to eliminate the noise in the image? – andrestoga Jul 9 '12 at 11:54
  • A quick and dirty solution would be to use morphological erosion-dilation, if you expect the noise objects to be really small. But this would affect your main object as well. – Leonidas K Jul 9 '12 at 18:52
  • Yes, that's the problem and I don't want to affect the main object. – andrestoga Jul 9 '12 at 23:35
  • Then I think your best bet would be to find the objects and discard the very small ones. I don't know how this is done in OpenCV, but @Abid mentioned contours in his answer. Once you have the objects, it's just a matter of setting a reasonable threshold on the number of pixels (based on the image something like 10-20 would do) to discard very small ones. I would also go for a simple non-linear filter that checks the number of non-zero elements in a large neighborhood (15x15). If it's under 10, zero the pixel. – Leonidas K Jul 10 '12 at 10:40

First question :

It is ok to do so since you have single object in image. If more objects, and want to find moments for each, use contours. Visit : http://opencvpython.blogspot.in/2012/06/contours-3-extraction.html

Second Question :

(I am too thinking about it after seeing your questions)

HuMoments were brought to light by Mr.Ming Kuei Hu in his paper " Visual Pattern Recognition by Moment Invariants " in 1962.

In that paper, he explains them ( with help of high mathematics content, of course). You can check it if you need.

He states :

Theorem: The central moments are invariants under translation.

When you find the moments using moments() function, it returns three types of moments, spatial moments (Mji), Central Moments (MUji) and Central Normalized Moments ( NUji). Check out the docs for moments()

At the end of section 4-C, Hu states that, out of seven relations ( Visit here to see them), first six are invariant to translation, size and rotation, while seventh one is skew invariant, which helps to distinguish mirror images.

I searched a lot about what Hu Moments values means. But all papers says the same dialog : " Seven Hu Moments are calculated from Central Moments which are invariant to size, position and orientation ". They don't say what individual values mean.

And the classical book of OpenCV "Learning OpenCV" by Mr.Gary Bradsky has given some insights telling us to explore more. (Refer page 254)

  • 2
    Thanks @Abid. I'm really surprised not to find on the Internet some sample picture illustrating what moments correspond to visually. It seems not very difficult to produce some pictures illustrating them. One could compute moments for a set of points and adjust their positions using any optimization algorithm until an configuration is found where, say, a particular moment is 1 while the other are 0, etc. For example, isn't hu[0] like the eccentricity of an ellipse? It could be illustrated with 3 points forming an isosceles triangle, or four points in a diamond shape. Anyone? – Stéphane Gourichon Sep 26 '15 at 20:22

To answer your second question:

I don't think the invariant moments have any meaning. They're simply guaranteed to be constant for a given shape, no matter how it's shifted, rotated, or scaled.

The kind of meaning you sound like you'd like to know about them:

what data is related to rotation, what for translation and what for scale change?

doesn't quite make sense since by definition, they are all not related to rotation, translation, and scale. However, once could easily ask a similar question but for other properties, for example:

what data is related number of corners, roundness, or width to height ratio?

Here I think it's obvious that these moments don't relate to any arbitrary property one would like it to relate to so the answer again is there is no meaning.

So where does that leave us? With this: if we want to compare two objects to tell if their "shape" is similar (and by "shape" we mean that we don't care about rotation, translation, and scale changes), we can calculate the hu invariant moments and compare them. If these values are "approximately" equal, then you can hopefully say that the shapes are "approximately" the same. One would then hope that these moments vary wildly between different shapes - and whether they do or not is an interesting question that maybe someone else can answer.

For example, lets say we calculate some of the the moments (only showing three and with ranges 0 to 1 for simplicity) of a square as:

(0.5, 0.5, 0.5)

We would then hope that a circle gives something like:

(0.5, 1, 0.5)

And an oval:

(0.5, 1, 0.7)

This may allow you to compare these shapes. If you calculate the moments of an unknown shape and get:

(0.51, 0.98, 0.47)

it's probably (hopefully) a circle. If however a star gave you:

(0.2, 0.6, 0.9)

and a crescent also gave the same thing, that wouldn't be so useful. With seven moments though, there's quite a bit of potential for at least a few of the moments to vary significantly for what we may consider important features of a shape.

Hope this helps.

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