I have a height map of NxN values.

I would like to find, given a point A (the red dot), whose x and y coordinates are given (and z is known from the data, so A is a vertex of the surface) a set of points that lie on the circumference of the circle with center in A and radius R that are a good approximation of a circular "cloth" (in grey) draped on the imaginary surface described by the data points.

The sampling, the reciprocal distances between the set of points that I am trying to find, doesn't need to be uniform, but still I would like to find at least all the points that are an intersection of the edges of the mesh with the circle at distance R from A.

How to find this set of points?

Is this a known problem?

-- edit

The assumption that Jan is using is right: the samples form a regular rectangular or square grid (in the X-Y plane) aligned with [0,0]. But I would like to take the displacement in the Z direction into account to compute the distance. you can see the height map as a terrain, and the algorithm I am looking for as the instructions to give to an explorer that, traveling just on paths of given latitude or longitude, mark the points that are at distance R from A. Walking distance, that is taking into account all the Z displacements done so far. The explorer climbs and go down in the valleys too.

The trivial algorithm for this would be something like this. We know that given R, the maximum displacement on the x and y axis corresponds to a completely flat surface. If there is no slope, the x,y points will all be in the bounding square Ax-R < x < Ax+r and Ay-R

At this point, it would start traveling to the close cells, since if the perimeter enters the edge of one cell of the grid, it also have to exit that cell.

`[X,Y]`

space (top-down view), then it boils down to the Pythagorean theorem. If It's a circle in the`[X,Y,Z]`

space, then the circle does not lie on the surface. If you mean a sphere, then take the samples from top-down and filter. – Jan Dvorak Nov 26 '12 at 9:20