It's more common to think of a line in rectangle coordinates, i.e. *y = mx + b*. As the Wikipedia article states, a line can also be expressed in polar form. The Hough transform exploits this change of representation (for lines, anyway. The discussion can also be applied to circles, ellipses, etc.).

The first step in the Hough transform is to reduce the image to a set of edges. The Canny is edge-detector is a frequent choice. The resulting edge image serves as the input to the Hough process.

To summarize, pixels "lit" in the edge image are converted to polar form, i.e. their position is represented using a direction *theta* and a distance *r* - instead of *x* and *y*. (The center of the image is commonly used as the reference point for this change of coordinates.)

The Hough transform is essentially a histogram. Edge pixels mapping to the same theta and r area assumed to define a line in the image. To compute the frequency of occurrence, *theta* and *r* are discretized (partitioned into a number of bins). Once all edge pixels have been converted to polar form, the bins are analyzed to determine the lines in the original image.

It is common to look for the *N* most frequent parameters - or threshold the parameters such that counts smaller than some *n* are ignored.

I'm not sure this answer is any better than the sources you originally presented - is there a particular point that you are stuck on?