Abstract
The deflectometry provides a feasible way for surface testing with a high dynamic range, and the calibration is a key issue in the testing. A computer-aided testing method based on reverse Hartmann test, a fringe-illumination deflectometry, is proposed for high-accuracy testing of reflective surfaces. The virtual "null" testing of surface error is achieved based on ray tracing of the modeled test system. Due to the off-axis configuration in the test system, it places ultra-high requirement on the calibration of system geometry. The system modeling error can introduce significant residual systematic error in the testing results, especially in the cases of convex surface and small working distance. A calibration method based on the computer-aided reverse optimization with iterative ray tracing is proposed for the high-accuracy testing of reflective surface. Both the computer simulation and experiments have been carried out to demonstrate the feasibility of the proposed measurement method, and good measurement accuracy has been achieved. The proposed method can achieve the measurement accuracy comparable to the interferometric method, even with the large system geometry calibration error, providing a feasible way to address the uncertainty on the calibration of system geometry.
Highlights
The development of optical design and fabrication has placed ultrahigh requirement on the precision of measurement tools
A software configurable optical test system (SCOTS) [11,12,13,14], which is based on fringe reflection/deflectometry, was developed at the University of Arizona
A computer-aided fringe-illumination deflectometric method, which is based on the configuration of reverse Hartmann test system (RHTS) like SCOTS, is presented to achieve the high-accuracy testing of reflective surfaces, including the convex surface testing and small working distance
Summary
The development of optical design and fabrication has placed ultrahigh requirement on the precision of measurement tools. A software configurable optical test system (SCOTS) [11,12,13,14], which is based on fringe reflection/deflectometry, was developed at the University of Arizona It provides a contact-free, high dynamic range, full field metrology method with simple system setup and alignment. The achievable measurement accuracy of the auxiliary calibration tool is in the order of microns, it can introduce significant residual systematic error in the off-axis configuration like SCOTS, especially in the cases such as convex surface testing and small working distance (that is the distance between test surface and test system). A computer-aided fringe-illumination deflectometric method, which is based on the configuration of reverse Hartmann test system (RHTS) like SCOTS, is presented to achieve the high-accuracy testing of reflective surfaces, including the convex surface testing and small working distance. The test surface error can be calculated from the slope differences (Δwx, Δwy)
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