## Idea

This is an idea of how you could do it, I haven't tested it but my gut tells me it might work. I'm assuming that there will be slight differences in the pose of the manequin as well as the camera attitude.

Let the original image be `A`

, and the clothed image be `B`

.

Take the difference `D = |A - B|`

, apply a median filter that is proportional to the largest deviation you expect from pose and camera attitude error: `Dmedian = Median(D, kernelsize)`

.

Quantize `Dmedian`

into a binary mask `Dmask = Q(Dmedian, threshold)`

using appropriate threshold values to obtain an **approximate** mask for the garment (this will be smaller than the garment itself due to the median filter). Reject any shapes in `Dmedian`

that have too small area by setting their pixels to 0.

Expand the shape(s) in `Dmask`

proportionally to the size of the median kernel into `Emask=expand(Dmask, k*kernelsize)`

. Then construct the difference in the masks `Fmask=|Dmask - Emask|`

which now contains areas of pixels where the garment edge is expected to be. For every pixel in `Fmask`

which is in this area, find the correlation `Cxy`

between `A`

and `B`

using a small neighbourhood, store the correlations into an image `C=1.0 - Corr(A,B, Fmask, n)`

.

Your final garment mask will be `M=C+Dmask`

.

## Explanation

Since your image has nice and continuous swatches of colour, the difference between the two similar images will be thin lines and small gradients where the pose and camera attitude is different. When taking a median filter of the difference image over a sufficiently large kernel, these lines will be removed because they are in a minority of the pixels.

The garment on the other hand will (hopefully) have a significant difference from the colors in the unclothed version. And will generate a bigger difference. Thresholding the difference after the median filter should give you a rough mask of the garment that is undersized dues to some of the pixels on the edge being rejected due to their median values being too low. You could stop here if the approximation is good enough for you.

By expanding the mask we obtained above we get a probable region for the "true" edge. The above process has served to narrow our search region for the true edge considerably and we can apply a more costly correlation search between the images along this edge to find where the garment is. High correlation means no carment and low correlation means garment.

We use the inverted correlation as an alpha value together with the initially smaller mask to obtain a alpha valued mask of the garment that can be used for extracting it.

## Clarification

Expand: What I mean by "expanding the mask" is to find the contour of the mask region and outsetting/growing/enlarging it to make it larger.

`Corr(A,B,Fmask,n)`

: Is just an arbitrarily chosen correlation function that gives correlation between pixels in `A`

and `B`

that are selected by the mask `Fmask`

using a region of size `n`

. The function returns `1.0`

for perfect match and `0.0`

for anti-match for each pixel tested. A good function is this pseudocode:

```
foreach px_pos in Fmask where Fmask[px_pos] == 1
Ap = subregion(A, px_pos, size) - mean(mean(A));
Bp = subregion(B, px_pos, size) - mean(mean(B))
Cxy = sum(sum(Ap .* Bp))*sum(sum(Ap .* Bp)) / (sum(sum(Ap.*Ap))*sum(sum(Bp.*Bp)))
C[px_pos] = 1.0 - Cxy;
end
```

where `subregion`

selects a region of size `size`

around the pixel with position `px_pos`

.
You can see that if `Ap == Bp`

then `Cxy=1`