DE3400389A1 - Two-beam interferometer arrangement, in particular for Fourier transform spectrometers - Google Patents

Abstract

The invention relates to optical two-beam interferometer arrangements such as are applied, in particular, in Fourier spectrometers. The aim of the invention is to construct an interferometer which is highly stable with regard to the state of adjustment and can be applied to a plurality of spectral regions. The object consists in compensating shock loads and vibration loads and temperature changes, and in permitting ease of exchange of the beam splitter. According to the invention, for this purpose two planar mirror surfaces are constructed as inherently rigid support bodies and arranged rotatably together with a double reflector subassembly in a longitudinal box profile, the beam splitter being exchangeable.

Description

Two-beam interferometer arrangement especially for

Eourier Transform Spectrometers The invention relates to optical Two-beam interferometer arrangements, such as those in particular in Fourier Spektro meters be applied.

Interferometer arrangements are known / 1 /, Dorenwendt, Grunert: A counting interferometer for determining angles. Precision engineering and measurement technology 84 (1976) 7, 5. 344, in which an incoming light beam by means of a Köster prism is divided into two parallel DeilbUndel.

The generated partial bundles are held by two roof mirrors that are fixed are arranged on a turntable at the same distance from the axis of rotation, and wherein the straight line connecting the roof edge intersects the axis of rotation, reflects and at the same time displaced parallel to themselves, then meet one firmly arranged plane mirror and are then returned to the Köster prism steered where they get to the interference.

A rotation of the table causes the roof mirrors to move in opposite directions, from which an optical gear undershoot results.

The division of the light beam into two parallel partial beams is at other known interferometer arrangements (/ 2 /, Davis. Larson Williams, Michel &Connes; Infrared Fourier Speotrometers for airborne and ground-based astronomy.

Applied Option, Vol. 19, No. 24, December 15, 1980) caused by the fact that A beam splitter is arranged between two plane mirrors standing at an obtuse angle to one another is.

Interferometers for use in the infrared spectral range can be used mostly constructed in such a way that transmission occurs only at the beam splitter, but otherwise only reflection on mirrored surfaces. This has the advantage that when changing of the spectral range only the beam splitter has to be changed, e.g. with Switch from near infrared to mid infrared.

When using an interferometer with a Köster prism you would have to change of the spectral range the SUsterprisma can be changed, which with the same aperture has significantly larger dimensions than a beam splitter made of plane-parallel plates, which is also made of technologically difficult to handle IR-transparent material, e.g. KBr for the middle infrared, would have to be manufactured, being it in the far infrared there are no suitable IR-transparent materials.

For these reasons, the use of an interferometer with a Köster prism only possible to a limited extent for the infrared spectral range. A beam splitter change must be excluded for practical reasons.

In the second interferometer arrangement, the disadvantages that arise Obtained from the application of a Köster prism bypassed by a plate beam splitter and two plane mirrors are used to generate parallel partial beams. The beam splitter is rigidly arranged and the two plane mirrors can each be individually adjusted parallel partial bundles are reflected by sliding cat's eyes.

The adjustment procedure for adjusting such an interferometer is described in detail in / 2 /. Just the elimination of the shear effect through Adjustment on the two plane mirrors takes place as a tedious, iterative one Process. Is there an intention to build an interferometer with an exchangeable beam splitter? this process must be repeated every time the beam splitter is changed, the method described in / 2 / for beam splitters that only operate in the infrared range work, i.e. do not have a beam splitter layer for the visible spectral region, is not applicable, so that the adjustment of such an interferometer proves extremely difficult.

An incorrect adjustment also affects the position of the interference pattern on the detector.

So it is easily possible that the center of the Ifydinger ring system, generally by means of imaging optics on a detector at the output of the Interferometer arises, is not in the middle of the detector. That leads to a considerable Reduction of the modulation depth in the measured interferogram and thus to a unacceptable reduction of the signal-independent signal-to-noise ratio, or to path difference errors in the interferogram and thus to errors in the calculated one Spectrum.

For the reasons given, this interferometer arrangement is also recommended not as a basis for an interferometer with a changeable beam splitter or with a beam splitter without a splitter layer for the visible spectral region for the purpose the adjustment of the interferometer.

The aim of the invention is to build an interferometer with respect to the adjustment state is highly stable and can be used for several spectral ranges is.

The invention is based on the object of an interferometer arrangement to create their animal state with respect to shock and vibration loads and temperature changes insensitive and with which a slight change of the beam splitter is possible.

According to the invention this is in an interferometer arrangement in which two parallel partial bundles generated by a beam splitter and two plane mirror surfaces be directed to one Spiegelanzdnung each, with the mirror assemblies on one common carrier body are arranged as a double reflector assembly and the carrier body is rotated around an axis so that the mirror assemblies in the direction of the generated parallel sub-bundles are moved in opposite directions, daduroh achieved that to avoid a rigid support body of relative movements between the plane mirror surfaces is constructed as a corner mirror with two fixed planar mirror surfaces, wherein the beam splitter is designed as an exchangeable assembly that is approximately is arranged parallel to the bisecting plane of the corner mirror assembly, that the corner mirror assembly to eliminate shear effects by adjustment is designed to be pivotable, its pivot axis being perpendicular to the plane 9 which is spanned by the two parallel sub-bundles that the pivot and Inertia axis of the corner mirror assembly coincide and that the beam splitter assembly tiltable about an axis lying parallel to the parallel sub-bundles for adjustment is arranged, the base body for the interferometer arrangement is according to the invention designed as a longitudinal box profile with one or more central webs, the double reflector assembly is over two shaft ends through a bearing point each in the top bar and the bottom bar of the longitudinal box profile rotatable on one side within the longitudinal box profile stored, the corner mirror is on the opposite side arranged within the longitudinal box profile and between the reflector assembly and the corner mirror, the beam splitter and the central web are arranged, wherein for introducing the beam splitter into the longitudinal box profile in the top bar or a break is made in the lower bar.

The particular advantage of the arrangement according to the invention is that that with a rigid design of the corner mirror, the angle between any two rays of the two sub-bundles in the interferometer, even when pivoted of the corner mirror remains unchanged. This means that parallel beams also remain when swiveled parallel. That means that it works for two through beam splitting and reflection at the corner mirror resulting parallel rays can only give one position of the angle mirror, in which eliminates the shear effect o Only the use of a rigid corner mirror has the advantage that the Hydinger ring system created in the detector plane is in the shear-free state to the detector always has the same position. That is a necessary one A prerequisite for a simple replacement of the jet because it is the center of the Bydinger ring system must always fall on the detector.

With this structure, it is possible to use the optical assemblies outside of the Interferometers, e.g. the imaging optics for the detector and the detector itself, to adjust in the visible spectral range Another advantage of the invention Arrangement consists in that nodding movements such as those caused by shocks, vibrations and Temperature effects are generated with respect to the adjusted state of the interferometer and the optical path difference remain without effects, because they inherently Rigid arrangement of the corner mirror nodding movements in the same direction affect the angle of reflection of the partial bundles on the flat mirror surfaces.

A translational movement of the caused by external disturbances in itself rigid angle mirror in the direction of the parallel partial bundle is with respect to the optical path difference, the adjustment status and the shear effect this type of arrangement also has no effect.

By the coincidence chosen in the inventive arrangement of Sohwenk- and axis of inertia of the angle mirror is prevented by the Acceleration forces, such as those caused by shocks and vibrations, are rotary Acceleration components occur at the rigid angle mirror that lead to undesirable Shear effects or optical path difference changes lead.

Another particular advantage of the inventive solution arises by designing the base body as a longitudinal box profile with one or more Central bars to accommodate the double reflector assembly, the beam splitter and the Corner mirror.

The optical components are mechanically on the shortest path to each other connected The longitudinal box profile with the central webs is very rigid and torsion-resistant, so that a high positional stability of the optical components with a relatively low mass is achieved.

The symmetry of the profile causes the changing ambient temperature of relatively little influence on sensitive changes in relative position is the upper and lower bar of the longitudinal box profile are used to accommodate the bearings of the Double reflector assembly for direct mounting on a spectrometer plate or for Assemble adjustment elements and the drive for the double reflector assembly. The introduction of the beam splitter through the opening in the upper or lower bar is easy to carry out and allows the beam splitter to be changed quickly.

Overall, the choice of the longitudinal box profile results in a constructive one simple, highly stable and functional arrangement.

The invention is to be explained in more detail using an exemplary embodiment. For this purpose, the figure shows a schematic arrangement of the interferometer assembly.

As shown in the figure, the light beam A hits through a light source is generated on a beam splitter 1. The beam splitter 1 is between two planar mirror surfaces 2 and 3 are arranged which belong to an angle mirror 4.

The beam splitter 1 is replaceable and is approximately parallel to Angle bisecting plane of mirror surfaces 2 and 3. By dividing the light beam A on the beam splitter 1 and a subsequent reflection on the mirror surfaces 2 and 3, the light bundle A is split into two parallel partial bundles B and C. These parallel Sub-bundles B and C then meet a 90 ° roof edge game gel 5 and 6th

The roof edge mirrors 5 and 6 are part of a common double reflector assembly 7, with two aligned shaft ends 8 and 9 or with one through going shaft is rigidly connected. The shaft ends 8 and 9 or the continuous The shaft is rotatably mounted in the middle between the roof mirrors 5 and 6 The bearings 10 and 11 of the shaft ends 8 and 9 or

the continuous shaft are aligned in the Oberlei ste 14 and bottom bar 15.

A rotational movement to generate an optical path difference is driven by a suitable drive on a shaft end 8 or 9 or on the continuous Wave generated.

The partial bundles reflected by the 90 ° roof edge mirrors 5 and 6 3 and. C always remain parallel and hit the beam splitter 1, where they recombine.

The interfering beams B 'and C' leave the interferometer output side, while the interfering beams B "and C" the interferometer exit via the entry page.

The optical path difference x is obtained by rotating the double reflector assembly 7 by the angle #, which extends over the distance from the roof edge D to 2 2 D calculated. It is # = 0 if the parallel sub-bundles B and C are perpendicular to the Meet the line connecting the roof edges.

The optical components of the interferometer, the corner mirror 4, beam splitter 1 and double reflector assembly 7 are in the free holes a longitudinal box profile 12 with a central web 13. The parallel sub-bundles B and C extend parallel to the top bar 14 and bottom bar 15 of the longitudinal box profile 12, with the central web 13 lying between them. The top and bottom bars 14 and 15 are used for direct mounting on a spectrometer plate or for mounting of adjustment elements and the drive for the double reflector assembly 7.

The beam splitter 1 is with version through a break 14 in the Upper bar 14 or lower bar 15 inserted.

Claims (2)

Invention claim: two-beam interferometer arrangement with the two Parallel partial bundles generated via a beam splitter and two plane mirror surfaces be directed to one mirror assembly each, the mirror assemblies on one common carrier body are arranged as a double reflector assembly, and the carrier body is rotated about an axis so that the mirror assemblies move in opposite directions in the direction of the generated parallel sub-bundles, characterized in that that in order to avoid relative movements between the planar mirror surfaces Rigid support body with two fixed plan mirror surfaces as Angled mirror is constructed, with the beam splitter as a replaceable assembly is executed, which is approximately parallel to the bisecting plane of the corner mirror assembly is arranged that the corner mirror assembly for ßliminierung of shear effects is designed to be pivotable, its pivot axis being perpendicular to the plane which is spanned by the two parallel sub-bundles that the pivot and The axis of inertia of the corner mirror assembly coincide, and that the beam splitter about an axis lying parallel to the parallel sub-bundles for adjusting the Interferometer is arranged tiltable. 2. Basic body for a two-beam interferometer arrangement according to point 1, characterized daduroh that the base body as a longitudinal box profile (12) with a or more central webs (13) is formed that the double reflector assembly (7) over two shaft ends (8) and (9) through one bearing point (10) and (11) each in the top bar (14) and the bottom bar (15) of the longitudinal box profile (12) on one side is rotatably mounted within the longitudinal box profile (12) that the corner mirror (4) arranged on the opposite side within the longitudinal box profile (12) is, and that between the double reflector assembly (7) and the corner mirror (4) the beam splitter (i) and the central web (13) are arranged, for introduction of the beam splitter (1) in the longitudinal box profile (12) in the top bar (14) or 4 an opening (16) is made in the lower bar (15).