Abstract
We present a calibration method for finding the coordinates of points in the trajectory of the scanning beam in flying-spot imaging devices. Our method is based on laterally translating the field of view on the imaging object plane by introducing additional beam deflections. We show that laterally translating the field of view provides a series of images whose relative translations are equal to the distances between the points in the scanning pattern to be calibrated. We show how these distances are mapped to the coordinates of the trajectory points. As an example, we demonstrate the calibration of the scanning patterns in an optical system with two independent microelectromechanical system based scanners. Our method profits from a large collection of distance measurements to find the trajectory coordinates, thereby minimizing the effect of random sources of uncertainty in the positions of points in the scanning pattern. We have found that we are capable of finding the coordinates of points in the scanning patterns with accuracy greater than the optical resolution of the imaging system.
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