High-accuracy three-dimensional aspheric mirror measurement with nanoprofiler based on normal vector tracing method

•High-precision free-form surface measurement with a nanoprofiler is demonstrated.•Optional uncertainty components like reference surface are not included the nanoprofiler.•Sub-nanometer repeatability of aspheric surface measurements was achieved.•Three-dimensional measurement is achieved with small...

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Bibliographic Details
Published in:Optics and lasers in engineering 2017-11, Vol.98, p.159-162
Main Authors: Kudo, Ryota, Kitayama, Takao, Tokuta, Yusuke, Shiraji, Hiroki, Nakano, Motohiro, Yamamura, Kazuya, Endo, Katsuyoshi
Format: Article
Language:English
Subjects:
Aspheric optics
Free-form optics
High-precision surface measurement
Non-contact measurement
Normal vector tracing
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Summary:•High-precision free-form surface measurement with a nanoprofiler is demonstrated.•Optional uncertainty components like reference surface are not included the nanoprofiler.•Sub-nanometer repeatability of aspheric surface measurements was achieved.•Three-dimensional measurement is achieved with small radius curvature aspheric surface.•The nanoprofiler and interferometer results agreed to within the systematic error. The demand for high-accuracy aspheric optical elements has increased significantly in recent years. The surface shapes of such optical elements must be measured with 1 nm Peak-to-Valley(PV) accuracy; however, it is difficult to achieve 1 nm PV accuracy with conventional methods. In this research, we developed a nanoprofiler based on the normal vector tracing method that can achieve the required accuracy. An aspheric mirror was measured by using the nanoprofiler, and repeatable, sub-nanometer measurements were achieved. Furthermore, we compared our nanoprofiler results with those of a Fizeau interferometer and found that the difference was within the systematic error.
ISSN:0143-8166
1873-0302
DOI:10.1016/j.optlaseng.2017.06.024