You can solve (for some values of "solve") this problem using morphology. First, to make the image more uniform, remove irrelevant minima. One way to do this is using the h-dome transform for regional minima, which suppresses minima of height < `h`

. Now, we want to join the thin lines. That is accomplished by a morphological opening with a horizontal line of length `l`

. If the lines were merged, then the regional minima of the current image is the background. So we can fill holes to obtain the relevant components. The following code summarizes these tasks:

```
f = rgb2gray(imread('http://i.stack.imgur.com/02X9Z.jpg'));
hm = imhmin(f, h);
o = imopen(hm, strel('line', l, 0));
result = imfill(~imregionalmin(o), 'holes');
```

Now, you need to determine `h`

and `l`

. The parameter `h`

is expected to be easier since it is not related to the scale of the input, and in your example, values in the range [10, 30] work fine. To determine `l`

maybe a granulometry analysis could help. Another way is to check if the `result`

contains two significant connected components, corresponding to the bigger L shape and the region of the thin lines. There is no need to increase `l`

one by one, you could perform something that resembles a binary search.

Here are the `hm`

, `o`

and `result`

images with `h = 30`

and `l = 15`

(`l`

in [13, 19] works equally good here). This approach gives flexibility on parameter choosing, making it easier to pick/find good values.

To calculate the area in the space between the two largest components, we could merge them and simply count the black pixels inside the new connected component.