I am writing a function to draw an approximate circle on a square array (in Matlab, but the problem is mainly algorithmic).
The goal is to produce a mask for integrating light that falls on a portion of a CCD sensor from a diffraction-limited point source (whose diameter corresponds to a few pixels on the CCD array). In summary, the CCD sensor sees a pattern with revolution-symmetry, that has of course no obligation to be centered on one particular pixel of the CCD (see example image below).
Here is the algorithm that I currently use to produce my discretized circular mask, and which works partially (Matlab/Octave code):
xt = linspace(-xmax, xmax, npixels_cam); % in physical coordinates (meters) [X Y] = meshgrid(xt-center(1), xt-center(2)); % shifted coordinate matrices [Theta R] = cart2pol(X,Y); R = R'; % cart2pol uses a different convention for lines/columns mask = (R<=radius);
As you can see, my algorithm selects (sets to 1) all the pixels whose physical distance (in meters) is smaller or equal to a radius, which doesn't need to be an integer.
I feel like my algorithm may not be the best solution to this problem. In particular, I would like it to include the pixel in which the center is present, even when the radius is very small.
Any ideas ?
(See http://i.stack.imgur.com/3mZ5X.png for an example image of a diffraction-limited spot on a CCD camera).