Extract arbitrarily rotated plane of data from 3D array as 2D array

I have a 3D matrix of data in matlab, but I want to extract an arbitrarily rotated slice of data from that matrix and store it as a 2D matrix, which I can access. Similar to how the slice() function displays data sliced at any angle, except I would also like to be able to view and modify the data as if it were an array.

I have the coordinates of the pivot-point of the plane as well as the angles of rotation (in x, y and z axis), I have also calculated the equation of the plane in the form:

``````Ax + By + Cz = D
``````

and can extract a 3D matrix containing only the data that fall on that plane, but I don't know how to then convert that into a simple 2D array.

Another way of doing it would be to somehow rotate the source matrix in the opposite direction of the angle of the plane, so as to line up the plane of data with the XY axis, and simply extract that portion of the matrix, but I do not know if rotating a matrix like that is possible.

I hope this hasn't been answered elsewhere, I've been googling it all day, but none of the problems seem to exactly match mine.

Thanks

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Do you need only the data that falls exactly on the plane (which in general will be very small amount of data points) or do tou want to interpolate the data? –  yohai Feb 1 '12 at 7:50
I want to return the nearest cells instead of interpolation, although interpolation will be considered later –  Nick Udell Feb 1 '12 at 12:02
To be clear you have a matrix with 3 indeces `A[i,j,k]=a_ijk` and you want to create an array of 2 indeces `B[u,v]=b_uv` where `u`,`v` are coordinate on a plane/slice of the `i`,`j`,`k` world? (and all indeces are integers) Also, is there some convention on which `ijk` corresponds to `u=1` and `v=1` ? –  ja72 May 2 '12 at 12:45

You can take a look at the code here. I think the function is similar to what you are trying to solve.

The function extracts an arbitrary plane from a volume given the size of the plane, the center point of the plane, and the plane normal, i.e. [A,B,C]. It also outputs the volumetric index and coordinate of each pixel on the plane.

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Aha! May have just solved it myself.

To produce the plane equation I rotate a normal vector of (0,0,1) using rotation matrices and then find D. If I also rotate the following vectors:

``````(1,0,0) //step in the x direction of our 2D array
``````

and

``````(0,1,0) //step in the y direction of our 2D array
``````

I'll have the gradients that denote how much my coordinates in x,y,z have to change before I step to the next column in my array, or to the next row.

I'll mock this up ASAP and mark it as the answer if it works

EDIT: Ok slight alteration, when I'm rotating my vectors I should also rotate the point in 3D space that represents the xyz coordinates of x=0,y=0,z=0 (although I'm rotating around the centre of the structure, so it's actually -sizex/2,-sizey/2,-sizez/2, where size is the size of the data, and then I simply add size/2 to each coordinate after the rotations to translate it back to where it should be).

Now that I have the gradient change in 3D as I increase the x coordinate of my 2D array and the gradient change as I increase the y coordinate, I can simply loop through all possible x and y coordinates (the resulting array will be 50x50 for a 50x50x50 array, I'm not sure what it will be for irregular sizes, which I'll need to work out eventually) in my 2D array and calculate the resulting 3D coordinates on my plane in the data. My rotated corner value serves as the starting point. Hooray!

Just got to work out a good test for this encompassing all angles and then I'll approve this as an answer

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