Interferometer for Monitoring Convex Hyperbolic Surfaces of Small Diameters
Authors: Timashova L.N., Kulakova N.N. | Published: 27.09.2022 |
Published in issue: #3(140)/2022 | |
DOI: 10.18698/0236-3933-2022-3-115-130 | |
Category: Instrument Engineering, Metrology, Information-Measuring Instruments and Systems | Chapter: Optical and Optoelectronic Instruments and Complexes | |
Keywords: fizeau interferometer, convex hyperbolic mirror, optical surface quality control, wave aberration, Fourier transform |
Abstract
We used Fourier transforms to perform a theoretical analysis of how the process of interference pattern formation in a laboratory-scale Fizeau laser interferometer is affected by the error in the working wave front. The interferometer is designed to monitor convex hyperbolic surfaces characterised by small diameters and low aperture angles. We indicate their application scope. The interferometer consists of a laser illuminator, a microlens, a beam splitter, that is, a thin plane-parallel plate with a semitransparent coating on its front surface, and a screen. A thin translucent plate located perpendicular to the line connecting the geometric foci of the hyperbolic surface acts as a separator and a reference simultaneously. The paper provides the main equations describing the wave aberration of the working branch and the position of optical elements in the interferometer design. We present an example of computing aberration in the working branch of the interferometer. This calculation reveals that aberrations in the thin plane-parallel plate can be discarded at low aperture angles. The interferometer forms a high-precision optical surface map, that is, interference band distortion caused by the interferometer error does not exceed 0.1 of the distortion caused by the error inherent to the surface being monitored. The interferometer provides highly accurate measurement of hyperbolic surfaces while featuring an obviously simple design
Please cite this article in English as:
Timashova L.N., Kulakova N.N. Interferometer for monitoring convex hyperbolic surfaces of small diameters. Herald of the Bauman Moscow State Technical University, Series Instrument Engineering, 2022, no. 3 (140), pp. 115--130 (in Russ.). DOI: https://doi.org/10.18698/0236-3933-2022-3-115-130
References
[1] Krivovyaz L.M., Puryaev D.T., Znamenskaya M.A. Praktika opticheskoy izmeritelnoy laboratorii [Practice of an optical measuring laboratory]. Moscow, Mashinostroenie Publ., 1974.
[2] Kreopalova G.V., Puryaev D.T. Issledovanie i kontrol opticheskikh system [Reserch and control on optical system]. Moscow, Mashinostroenie Publ., 1978.
[3] Kreopalova G.V., Lazareva N.L., Puryaev D.T. Opticheskie izmereniya [Optical measurements]. Moscow, Mashinostroenie Publ., 1987.
[4] Malacara D., ed. Optical shop testing. Hoboken, Wiley, 1978.
[5] Andreev A.N., Gavrilov E.V., Ishanin G.G., et al. Opticheskie izmereniya [Optical measurements]. Moscow, Logos Publ., 2008.
[6] Timashova L.N., Kulakova N.N. Interferometer to control wedge angles. Herald of the Bauman Moscow State Technical University, Series Instrument Engineering, 2020, no. 2 (131), pp. 117--129 (in Russ.). DOI: https://doi.org/10.18698/0236-3933-2020-2-117-129
[7] Schroder G., Treiber H. Technische Optik. Wurzburg, Vogel-Buchverlag, 2002.
[8] Mishin S.V., Kulakova N.N., Tirasishin A.V. Adaptation of the algorithm for searching the coordinates of the energy centre in the image of an autocollimating point for working with digital autocollimator. Herald of the Bauman Moscow State Technical University, Series Instrument Engineering, 2016, no. 2 (107), pp. 117--124 (in Russ.). DOI: https://doi.org/10.18698/0236-3933-2016-2-117-124
[9] Timashova L.N., Kulakova N.N., Sazonov V.N. Opto-electronic system for measurement of spherical aberration. Herald of the Bauman Moscow State Technical University, Series Instrument Engineering, 2018, no. 6 (123), pp. 112--122 (in Russ.).DOI: https://doi.org/10.18698/0236-3933-2018-6-112-122
[10] Kulakova N.N., Kaledin S.B., Sazonov V.N. Error analysis of IR lens focal length measured by a goniometric method. Herald of the Bauman Moscow State Technical University, Series Instrument Engineering, 2017, no. 4 (115), pp. 17--26 (in Russ.).DOI: https://doi.org/10.18698/0236-3933-2017-4-17-26
[11] Timashova L.N., Kulakova N.N. Analysis of interferometer with micro-mirror on beam splitting cube. Herald of the Bauman Moscow State Technical University, Series Instrument Engineering, 2021, no. 3 (136), pp. 129--143 (in Russ.). DOI: https://doi.org/10.18698/0236-3933-2021-3-129-143
[12] Mosyagin G.M., Nemtinov V.B., Lebedev E.N. Teoriya optiko-elektronnykh system [Theory of optic-electronic systems]. Moscow, Mashinostroenie Publ., 1990.
[13] Yakushenkov Yu.G. Proektirovanie optiko-elektronnykh priborov [Design of optic-electronic systems]. Moscow, Logos Publ., 2000.
[14] Yakushenkov Yu.G. Teoriya i raschet optiko-elektronnykh priborov [Theory and calculation of optic-electronic systems]. Moscow, Logos Publ., 1999.
[15] Korotaev V.V. Raschet shumovoy pogreshnosti optiko-elektronnykh priborov [Theory of optical systems]. St. Petersburg, NIU ITMO Publ., 2012.