# Pixels between 2 intersecting lines

I need to find pixel values that are between the intersection of 2 lines. The following image shows the points that I want namely the brown region.

These 4 co-ordinates can change and are not necessarily the corner points.

What is the fastest way to get the pixel values ? Is there any function that can give me the necessary mask.

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Do you always want the regions below one line and above another? What about the regions left of one line and right of another; those are also 'between' the lines. –  Isaac Nov 6 '12 at 5:49
I want the brown regions... –  anon Nov 6 '12 at 8:06
Are the lines always the diagonals of the image? –  Junuxx Nov 6 '12 at 14:43
Not necessary... –  anon Nov 6 '12 at 17:01

You should calculate for each point, whether it is above the line or below. If the line is given in its equation form `Ax+By+C`, then it is as simple as calculating the sign of this expression, per your point `(x,y)`. If your lines are given in any other form, you should first calculate the form above. (See here and here)

Let `L1` be the set of all points below the first line, and `L2` the set of all points below the second line. Then, your set is `X = Xor(L1,L2)`

[ ] Xor []

Equals:

Here is a Matlab code that solves you problem for the corner points, based on the solution that I've described. You can adjust the line equations in your code.

``````function CreateMask()
rows = 100;
cols = 200;
[X,Y] = ndgrid(1:cols,1:rows);

belowFirstLine  = X*(1/cols)  + Y*(-1/rows) + 0 < 0;
belowSecondLine = X*(-1/cols) + Y*(-1/rows) + 1 < 0;

figure;imshow( transpose(xor(belowSecondLine,belowFirstLine)));
end
``````
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Here is geometrical, rather than analytic solution.

First, you need to construct a mask image, initially filled with all zeroes. Then you should draw both lines using Bresenham's algorithm. There is no default implementation in Matlab, but you can pick one at Matlab Central. I assume, you have coordinates of intersections of the lines with image borders.

After that your image is divided into four areas and you need to flood-fill two of them using bwfill. And now you have the mask.

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Doesn't necessarily work: In degenerate cases flood fill doesn't necessarily find the only one or two pixels to be filled (which aren't necessarily even connected. Also this answer assumes that the points are in edges at least and finally I doubt that iterative approaches are really faster than matrices. –  Aki Suihkonen Nov 6 '12 at 6:43
Agree with all the points. –  Mikhail Nov 6 '12 at 7:24

You can start with generating two matrices with x & y coordinates:

`````` 1 2 3 4 5       1 1 1 1 1
1 2 3 4 5   vs. 2 2 2 2 2   sized as the region
1 2 3 4 5       3 3 3 3 3
``````

Then one needs 4 line equations that convert x*a + y*b < c into 4 masks: diagonals have to be XORED and top/bottom masks ANDED