Here is something to get you started. When jumping into new problems, I don't see much value in trying a lot of complex steps just because they are available somewhere to use. So my focus is on using relatively simple things, that will fail in more varied situations, but hopefully you will see its value and get some sense of the problem.

The approach is fully based on corner detection; two typical methods for this detection are the Harris detector or the one by Shi and Tomasi described in the paper "Good Features to Track", 1994. I will use the second one, just because there is a ready implementation in OpenCV, newer Matlab, and possibly many other places. Its implementation on these packages also allows for easier parameter adjustment, regarding corner quality and minimum distance between corners. So, suppose you can detect all corner points correctly, how do you measure how close one shape is to another one based on these points ? The images have arbitrary size, so my idea is to normalize the point coordinates to the range [0, 1]. This solves for the scaling issue, which is desired according to the original description. Now we have to compare point sets in the range [0, 1]. Here we go for the simplest thing: consider one point `p`

from the shape `a`

, what is the closest point in shape `b`

? We assume it is one with the minimum absolute different between this point `p`

and any point in `b`

. If we sum all the values, we get a scoring between shapes. The lower the score, the more similar the shapes (according to this approach).

Here are some shapes I drew:

Here are the detected corners:

As you can clearly see in this last set of images, the method will easily confuse a rectangle/square with a cylinder. To handle that you will need to combine the approach with other descriptors. Initially, a simple one that you might consider is the ratio between the shape's area and its bounding box area (which would give 1 for rectangle, and lower for cylinder).

With the method described above, here are the measurements between the first and second shapes, first and third shapes, ..., respectively: 0.02358485, 0.41350339, 0.30128458 0.4980852, 0.18031262. The second cube is a resized version of the first one, and as you see, they are very similar by this metric. The last shape is a resized version of the first cube but without keeping the aspect ratio, and the metric gives a much higher difference.

If you want to play with the code that performs this, here it is (in Python, depends on OpenCV, numpy):

```
import sys
import cv2 as cv
import numpy
inp = []
for fname in sys.argv[1:]:
img_color = cv.imread(fname)
img = cv.cvtColor(img_color, cv.COLOR_RGB2GRAY)
inp.append((img_color, img))
ptsets = []
# Corner detection parameters.
params = (
200, # max number of corners
0.01, # minimum quality level of corners
10, # minimum distance between corners
)
# Params for visual circle markers.
circle_radii = 3
circle_color = (255, 0, 0)
for i, (img_color, img) in enumerate(inp):
height, width = img.shape
cornerMap = cv.goodFeaturesToTrack(img, *params)
corner = numpy.array([c[0] for c in cornerMap])
for c in corner:
cv.circle(img_color, tuple(c), circle_radii, circle_color, -1)
# Just to visually check for correct corners.
cv.imwrite('temp_%d.png' % i, img_color)
# Convert corner coordinates to [0, 1]
cornerUnity = (corner - corner.min()) / (corner.max() - corner.min())
# You might want to use other descriptors here. XXX
ptsets.append(cornerUnity)
def compare_ptsets(p):
res = numpy.zeros(len(p))
base = p[0]
for i in xrange(1, len(p)):
sum_min_diff = sum(numpy.abs(p[i] - value).min() for value in base)
res[i] = sum_min_diff
return res
res = compare_ptsets(ptsets)
print res
```