Lets say you have one point (x, y), that moved to (x', y').

Then the center of rotation must lie on the line that is perpendicular to (x,y)-(x',y'), and that intersects the center (x,y)-(x',y').

Now take another point, (x2, y2), that moved to (x'2, y'2). This also gives rise to a line on which the center of rotation must be located on.

Now take these two lines and compute the intersection. There you have the center of rotation.

Update: If you don't have the correspondence of which point went where, it shouldn't be too hard to figure out. Here is a suggestion from top of my head: Find the center of mass of the "before"-points. Order the points according to their distance from this point. Now do the same with the "after"-points. The order of the two sets should now match. (The point closest to the center of mass *before* rotation, should be the point closest to the center of mass *after* rotation.)

rotateson its axis. Itrevolvesaround the Sun. To which are you referring? – San Jacinto Nov 4 '10 at 19:18