DE3531904A1 - Lateral shearing interferometer for phase-different measurement of two wave fronts of constant phase - Google Patents

Abstract

Lateral-shearing interferometer for phase-different measurement of wave fronts. This two-beam interferometer is used for measuring the deviation of a test wave front from a planar wave front, and for measuring the deviation from the spherical shape in the case of a slightly curved wave front. These measurements are used, for example, for testing optical systems. In this case, the lateral offset of the wave fronts at right angles to the propagation direction of the light, so-called lateral shear, is brought about only by mirrors and can be adjusted independently of the path-length difference of the sub-beam paths. The path lengths of the sub-beam paths can be tuned to zero, the white-light position, and do not influence the lateral shear.

Description

description

Lateral shearing interferometer for measuring the phase difference of two Wave surfaces of constant phase The invention relates to a lateral shearing interferometer, LSI, based on the principle of two-beam interference in which the lateral displacement, lateral-shear, and the phase difference of the wave surfaces leaving the interferometer can be set independently of each other.

Such an interferometer is used for testing flat or weak curved wave surfaces of constant phase, e.g. the visible range of the electromagnetic Radiation can be used. The flatness of such wave surfaces or the deviation from the spherical shape with slightly curved wave surfaces is a quality measure for the imaging performance, e.g. from camera lenses or micro lenses. Such a test item is available with this one LSI in the direction of light in front of the interferometer and is from a point-shaped object illuminated.

Previously known interferometers are the Twyman-Green interferometer, TGI, based on the Michelson interferometer, MI, where the test object is in the one arm of the interferometer is located and the light passes through it twice, s. Pr. Of Opt., P. 302.

The different variants of the Mach-Zehnder interfeometer, MZI, so the interferometer according to Bates, see Max Born & Emil Wolf, Principles of Optics, Sixth Edition, Pergamon Press, Frankfurt, chapter 7.5, page 315, and Drew, see Mütze, Foitzik, Krug and Schreiber, ABC der Optik, first edition, Verlag Werner Dausien, 1972 Hanau / Main, page 608.

The two prototypes MI and MZI can be adjusted to white light, i.e. the path length difference within the two partial beam paths can be made zero will.

This adjustment is necessary for a good contrast of the interference pattern. If such a device is expanded into a measuring interferometer, then there will be deviations from the prototype additional elements in the beam path within the interferometer, E.g. the test item itself with the TGI or compensation plates with the interferometer inserted after Bates. The Drew interferometer differs from the Basic position asymmetries of the two partial beam paths introduced. The measurand is in all cases the phase difference between two wave surfaces.

It now depends on whether those who cause the adjustment, or Elements inserted in the beam path have their effect on the law of refraction or reflection build up. If, for example, a plane-parallel plate is rotated within a partial beam path in the interferometer, it not only displaces the beam but also changes it optical path due to the wavelength dependence of the law of refraction different for different wavelengths. Such a structure requires in the other Partial beam path mostly a compensation element, similar to the compensation plate with the Michelson interferometer, to maintain the white light balance. At the TGI, for example, a second lens like the test object is required for exact white light balancing. Furthermore, this white light position usually has to be found anew for each measurement adjustment will.

The invention is based on the object of circumventing this problem.

This object is achieved according to the invention in that the measuring adjustments can only be carried out by the additional plane mirrors and that those at one Two-beam interferometer for splitting and merging the beam paths is mandatory necessary plane-parallel plates from the partial waves in the same main beam direction be enforced.

Care has been taken to ensure that the input to the interferometer symmetrical output is used, so that each of the beam splitters T1 and T2 the partial waves are only allowed through once and reflected once. Also are lateral shear and path length adjustment of the partial beam paths in this two-beam interferometer independently adjustable, so that with different measurement settings of the lateral-shear the white light balance is retained.

The advantages achieved with this invention are above all: that with the interferometer once calibrated to white light and independently of it adjustable lateral shear for testing lenses, only the filters in the illumination beam path must be changed for the different test wavelengths, so that the interference figures in the observation level to assess the imaging performance of the test object for these wavelengths are comparable without readjustment.

The diagram of the imaging beam path of the LSI in the basic position, lateral shear and phase difference identical to zero, is in Figures la and 1b shown. For the sake of clarity, only the main ray is drawn. The arrows perpendicular to the main ray correspond to the rotations of the wave fronts through the different reflections. At the interferometer output, the wave fronts have same orientation. Bl represents the point-like object for the test item Pr. The observation plane B is an image of the test object's exit pupil.

Furthermore, the additional flat mirrors S4 and through the Replaced mirror prism P in Figure 1b.

In Figure 2 there is a lateral shear opposite the dashed basic position, Image lb, drawn. In picture 3 the setting of the path length difference is opposite the basic position shown in Figure 1b.

Claims (3)

Claims (fN. Lateral Shearing Interferometer, LSI, according to 4m m Principle of two-beam interference for measuring the phase difference of two wave surfaces constant phase generated by a physical beam splitter T1 from the is the dividing surface of T1 which is not perpendicular to the wave surface, so that T1 is the Direction of propagation of the reflected part A of the original wave surface changes, the transmitted portion B does not change in its direction of propagation, and and a plane mirror S1, which shows the direction of propagation of the transmitted by T1 Part B or the mirrored part A changes so that the directions of propagation A and B are the same and parallel, by inserting two additional plane mirrors, S3 and S4, which change the directions of propagation of A and B so that the wave surfaces run towards each other at an angle less than 1800, penetrate each other and of two further plane mirrors, S5 and Sud, the directions of propagation of the components A and B can be changed so that they are in turn rectified and parallel and this common direction of propagation of A and B through a further arrangement, consisting of a plane mirror S2 and a physical beam splitter T2, which is identical in structure to the arrangement S1-T1, is changed so that the Partial wave surfaces of constant phase leaving the LSI, mutually parallel directions of propagation and move in the opposite direction if Sj is the direction of propagation of the of T1 has changed part B, or in the same direction if S1 the direction of propagation of the part A reflected by T1 has changed and for an exact white light balance absolutely necessary parallel to that on T; running in Propagate wavefront, characterized in that one of the additional flat mirror for the part A, which allow the wave surfaces to converge with one of the additional flat mirrors for the portion 3 that shows the direction of propagation align the wave surfaces again parallel on a first common base and the other from the additional plane mirrors for the portion B, which are the wave surfaces run towards each other, with the other of the additional flat mirrors for the portion A, which is again parallel to the direction of propagation of the wave surfaces align, is mounted on a second common base and each base is up a cross table is located, which consists of a first longitudinal guide parallel to the Direction of propagation behind S1 and T1 is movable in the direction of light by the path length difference the partial beam paths within the LSI without the lateral shear to change and from a second longitudinal guide that perpendicular to the direction of propagation behind S1 and T1 is movable in the direction of the light to the mutual displacement perpendicular to the direction of propagation, called lateral shear, at the exit of the LSI behind T2 in the direction of light without changing the path length difference of the partial beam paths to adjust. 2. LSI according to claim 1, characterized in that the reflective Surfaces of the additional plane mirrors, for the portion A, are parallel and likewise the reflective surfaces of the additional flat mirrors, for portion 3, parallel are. 3. LSI according to claim 1 and 2, characterized in that the additional planar mirrors mounted on the first base and / or the Mirrors mounted on the second base, through a single prism, its Roof surfaces are mirrored and take over the function of the individual mirrors, replace permit.