DD153323A5 - DEVICE FOR SUBJECTIVE REFLECTION DETERMINATION - Google Patents

Abstract

The invention relates to a device for the subjective determination of refraction, with which the refraction is possible in a particularly simple and rapid manner, preferably free-standing. For this purpose, the apparatus has a first optical element (3), which images optotypes (13) into its image-side focal plane, and a second optical element (4), which is rearranged in the optical beam, and which images the optotypes toward the eye (7) to be examined. on. The distance of the end-side focal point (4 deep f) of the second element (4) from the image-side focal point (F 'deep 3) of the first element (3) is veraenderbar for the purpose of refraction determination. With the device, the refraction value can be determined both for a spherical and for a cylindrical correction.

Description

Title of the invention

Device for subjective refraction determination

Field of application of the invention

The invention relates to a device for subjective Refiakti-5 onsbestimmung.

The determination of the refractive error of the eye, the refraction determination, can be done objectively or subjectively. The objective refraction determination is carried out with the aid of optical devices derived from the ophthalmoscope. In their application, the subject's mental involvement is not required. The refractive power of the eye is measured monocularly.

Characteristic of the known technical solutions

The result of the objective refraction determination is considered the starting value for the subsequent subjective examination. Decisive for the prescription of glasses or contact lenses is always the result of the subjective refraction determination, since only with it the examination of the binocular functions is possible.

The subjective refraction determination is carried out in the simplest case by using a test specimen and loose tasting glasses, which are set in succession after a particular system in front of the subject's eye. The subjective examination can be carried out faster and more accurately with the aid of spectacle determination devices (phoropters), in which the test tubes are accommodated in recessed discs. If two Recosscheiben connected in series and each of these discs has the number of η-test glasses, so you can set a total of n ² -Korrektionswerte. Another way to perform the subjective refraction determination, the ALVAREZ lenses.

The possibility of subjectively determining the refraction by means of granulation when illuminating a diffusely reflecting surface with laser light has not proven itself and has not found its way into practice.

The determination of ocular astigmatism by subjective means is carried out by various refraction methods using loose test tubes or spectacle determination devices in which the test tubes are accommodated in recessed discs. For the determination of astigmatism astigmatic lenses are used (cylindrical glasses or toric lenses), which must be rotatable about the optical axis in order to adjust the various occurring axis directions can.

Another option for the determination of ocular astigmatism is provided by STOKES 'cylindrical lens, consisting of two plane cylinders, which are rotated synchronously against each other. The superposed arrangement of two STOKES cylindrical lenses, whose axes enclose an angle of 45 °, makes the determination of astigmatism also possible, although a calculation process for determining the axis and the size of the resulting cylinder is to be performed. Other viable ways of determining astigmatism are currently unavailable.

Object of the invention

The aim of the invention is to simplify the refraction determination.

Explanation of the essence of the invention

The object of the invention is to provide a device for the subjective determination of fraction, with which the refraction is possible in a particularly simple and rapid manner and preferably takes place freely.

This object is achieved by a device for subjective refraction determination, which is characterized according to the invention by an optotypes in its image-side focal plane imaging first optical element and this in the optical beam path downstream, the optotypes to be examined eye imaging second optical element, wherein the Distance of the dingseitigen focus of the second element from the image-side focal point of the first element is variable.

With this device, rapid refraction is possible with respect to both spherical and astigmatic ametropia under conditions of clear vision. At the same time, the device is also suitable for performing Nahbrillenbestimmung without preschar of prisms or other elements "suitable.

embodiment

Furthermore, the invention will be described by means of embodiments with reference to the figures. From the figures show:

1 shows a first embodiment of the invention in side view;

Fig. 2 is a partial sectional view of Figure 1 taken along the line II-II;

Fig. 3 is a side view of another embodiment of the invention;

4 shows a section along the line IV-IV in Figure 3;

Fig. 5 is a schematic representation of another embodiment of the invention for binocular measurement of spherical and astigmatic refractive error;

FIG. 6 is a modified embodiment with respect to the embodiment shown in FIG. 1; FIG.

Fig. 7 shows another embodiment; and

Fig. S is a detail similar to Figure 2 in a modified embodiment.

In the embodiment shown in Figure 1, the apparatus 1 comprises a first lens 3 and a second lens 4, which are arranged one above the other so that their optical axes 8, 9 are parallel to each other. Opposite the two lenses 3, 4 is a totally reflecting optical element 6, which may be a totally reflecting prism or a totally reflecting mirror system, which reflects the rays emerging from the first lens 3 into the second lens 4. If the third optical element 6 is displaced parallel to the optical axes 8, 9, so that the optical interval between the lenses ^ 3, 4 is changed.

In the in-side focal plane F _{3 of} the first lens 3, the aperture diaphragm 10, which coincides with the entrance pupil, is arranged. The exit pupil 11 of the system has a constant position with any adjustment of the third optical system 6 and is for each setting in the image-side focal plane Fj of the second lens 4. Between the second lens 4 and the exit pupil 11, a semitransparent plane mirror 12 is arranged with the optical axis 9 of the lens-4 at an angle of 45 °. includes. The visual sample 13 is viewed via a collimator 14. In the embodiment shown is carried out by a mirror 15, a deflection of the beam path, which is intended to effect only a structural shortening of the device.

If the third optical element 6, which is referred to below as the prism 6, adjusted so that the image-side focal point FA of the first lens 3 coincides with the dingseitigen focus F. of the second lens 4, so leave on the first lens 3 parallel incident rays the system of the lenses 3 and 4 again in parallel. On

right eye sees clearly the optotype 13 shown by the collimator 14 to infinity. This setting corresponds to the refraction value 0.0 dpt. If the prism 6 approaches the two lenses 3, 4, then the rays incident in the axis parallel to the first lens leave the second lens 4 divergent. A distant object is sharply seen by a shortsighted eye corresponding refraction. The displacement of the prism in the direction of the lenses thus corresponds to short-sighted refraction values, wherein there is a linear relationship between the position of the prism 6 and the extent of myopia. The magnitude of the displacement of the prism to the size of myopia is dependent only on the focal length of the second lens 4. Conversely, results from the displacement of the prism 6 in the opposite direction, ie away from the two lenses 3, 4, the setting for clear eyes. Beams entering the system in parallel converge out of the system of the two lenses. By calibrating a scale indicating the position of the prism 6, the determined refraction value can be read directly.

When forming the first optical element 3 and the second optical element 4 as spherical lenses, a STOKES'sehe cylindrical lens 16 is advantageously arranged for correcting the astigmatism at the location of the aperture diaphragm 10. This is rotatable about the optical axis to determine the axis position of the astigmatism. The values determined by means of the STOKES 'cylindrical lens can be utilized directly if the two lenses 3, 4 have the same focal length. At different focal lengths of the two lenses, a correction factor is to be applied, which results from the quotient of the refractive powers of the two lenses.

Instead of the described STOKES 'cylindrical lens 16, a fixed STOKES'sehe lens combination can be used, the axes of which include a constant angle of 45 °. Thus, the two components of cylinder effects of different sizes and arbitrary axis directions can be adjusted. Of course, the astigmatism could also be determined by means of a normal pedicle cross cylinder, wherein the pedicle cross cylinder should preferably be kept in the plane of the aperture stop.

If the measuring range of the spherical effect arising from the two lenses 3 and 8 is to be widened, additional lenses can be arranged in or near the plane of the aperture stop 10. Their effect corresponds directly to the correction values, as long as the lenses 3, 4 have the same focal length. Otherwise, a correction factor must be taken into account.

As already stated above, the exit pupil 11 lies in the image-side focal plane of the second lens 4 with each adjustment of the prism 6. During the measurement, the pupil (main plane) of the subject's eye 7 may coincide with the exit pupil 11. Then the so-called main point refraction is determined. If the subject pupil is located at a distance of 16 mm behind the exit pupil 11, the correction values for a spectacle lens vertex distance of 16 mm result. The distance of the pupil from the exit pupil 11 is thus identical to the vertex distance of the correction glasses. As indicated in Figure 2, the device comprises a support 17, which may be formed as a chin or forehead support, on which the head of the subject is supported and for adjusting the distance of the pupil of the subject from the exit pupil 11 relative to the housing - and is movable.

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The subject observes the visual sample 13 imaged infinitely via the collimator 14 by looking perpendicularly to the plane of the drawing in FIG. 1 onto the semitransparent mirror 12, which is arranged at an angle of 4.sup.5 ° to the optical axis 9. Through the mirror 12, the subject sees the free space at the same time as the visual sample 13, which may include optotypes or test figures. In this way, a free-standing refraction determination, in which the field of view of the patient is not narrowed and thus eliminates disturbing effects such as instrumentation myopia from the outset.

As is apparent from the above, by means of the device according to the invention described a continuous adjustment of the correction effect by moving the prism 6 is possible. Spherical correction values can be determined very quickly, with spherical aberrations being able to determine the full correction and, in the case of astigmatic deviations, the so-called best spherical correction. The awkward change of glasses is eliminated, and the subject may u.U. even make the optimum adjustment.

The astigmatic correction effect can also be adjusted continuously from 0 to a maximum value with the aid of STOKES 'cylindrical lens 16. Here, too, finding the correct axis position and determining the full correction is possible very quickly.

The exemplary embodiment illustrated in FIG. 3 serves primarily to determine the astigmatic correction values. In the apparatus shown, the first and second optical elements are designed as cylindrical lenses 18, 19. These are each held in a socket 20, 21, the on

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their outer periphery each have a sprocket. The mounting of the sockets takes place in such a way that upon rotation of the socket 20, the socket 21 rotates at the same angle in the opposite direction. The cylindrical lenses 18, 19 are held in the sockets in such a way that the axial position of a main section of both cylindrical lenses is parallel to one another in the manner shown in FIG. In the beam path, in the embodiment shown before. first cylindrical lens 18, a DOVE prism 22 is arranged.

This is rotatably arranged in the beam path via a schematically indicated mechanical coupling 24 so that its base 23 is aligned parallel to the axis 25 of the first cylindrical lens 18. Otherwise, in this embodiment the prism 6, the mirror 15, is the one above the collimator 14 and the aperture aperture coinciding in the focal length of the effective main section of the cylindrical lens 18 and the coincident entrance pupil with respect to arrangement and effect with those in Figure 1. The exit pupil 11 is again independent of the Positioning of the prism 6 at the location of the image-side focal length of the main section of the cylindrical lens 19. The observation is carried out in the same manner as in the first embodiment via a semi-transparent mirror 26 which is arranged so that the subject simultaneously with the vision sample shown at infinity also sees the free space.

The purpose of the DOVE prism 22 is to compensate for the rotation of the visual sample to be observed caused by the rotation of the cylindrical lenses 18, 19, so that the subject has the impression of a torsionally fixed visual sample.

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For refraction, the prism 6 is adjusted so that the image-side focal point or the focal line of the first cylindrical lens 18 coincides with the dingseitigen focal point or the focal line of the second cylindrical lens 19. If the right-looking observer eye is located near the image-side focal point of the second cylindrical lens 19, then it can observe distant objects sharply and without distortion in this position. If the eye to be examined has a simple myopic astigmatism, the astigmatism can be corrected by displacing the prism 6 in the direction of the cylindrical lenses 18, 19. By subsequently rotating the cylindrical lenses 18, 19 by means of the frames 20, 21 forming gears here the correct axis position is set. If the eye to be examined has a simple, clear astigmatism, the prism 6 must be adjusted away from the cylindrical lenses 18, 19.

If the DOVE prism 22 were not used, rotating the cylindrical lenses would cause the observed image to rotate. It would be possible to use a fixed stick figure 13 for testing the astigmatism. The image of the stick figure would then each time when turning - the cylindrical lenses 18, 19 move to the position in which it is seen sharply by the subject. If one wants to do without the image rotation, this is achieved by arranging a DOVE prism or another suitable image-rotating reversion element.

Should in addition to the embodiment shown. Spherical correction values are also determined, spherical lenses are used in the entrance pupil or aperture diaphragm 10 instead of the STOKES cylindrical lenses described in the first exemplary embodiment.

With the described embodiment, it is possible to determine the astigmatism and its position of a refractive eye in a particularly quick and simple manner and with continuous adjustment.

Suitably, the two cylindrical lenses 18, 19 are formed in Fig. As a plan cylinder, which have the same focal length. This has the advantage that depending on the setting of the prism 6 always only the cylinder effect changes in a main section, in the perpendicular main section but no visual effect is present. The axis position of the effective main section is adjusted in the manner described by rotating the cylindrical lenses. In this way it is achieved that the changing in known methods and devices for determining the astigmatism when changing the astigmatic value always changing spherical effect remains unchanged and thus the constant Nachkorrigieren the spherical effect can be omitted with changed astigmatic value.

In principle, it may be expedient to omit the DOVE prism 22 and to utilize the image rotation resulting from the rotation of the cylindrical lenses 18, 19 for refraction determination. It then took to find the main sections no rotatable test objects to use. However, special optotypes would then have to be used, since with normal optotypes in the case of a slanted axis position they are displayed askew.

In the embodiment of the device according to the invention shown in FIG. 5, two symmetrical beam paths 37, 38 are provided for binocular refraction determination. Both beam paths 37, 38 have exactly the same elements,

so only one is described. The elements in the beam path 37, which correspond to those in Figures 1 to 4, are each denoted by the same reference numerals, and corresponding to the elements of the first beam path 37 elements in the second beam path are marked with corresponding apostrophierten reference numerals.

The beam path seen from the visual sample initially agrees completely with the beam path shown in FIG. 3 and differs only in that, instead of the semitransparent mirror 26, a completely reflecting plane mirror 2 7 is provided. The part of the apparatus corresponding to the first embodiment shown in FIG. 3 is the part of the aperture diaphragm 10, mirror 15, first lens 3, displaceable prism 46, second lens 4, semitransparent mirror 12 and support 17 which is described with reference to FIGS arranged downstream there axisymmetric system. The arrangement of the second part takes place so that the aperture diaphragm 10 of the axisymmetric system of Figure 1 coincides with the exit pupil 11 of the first anamorphotic system corresponding to the representation in Figure 3. With this combined system, the adjustment of the spherical correction values, the astigmatic correction values and the determination of the axis position is possible in a simple and fast manner without any lenses being added for all values continuously under the condition of fine vision.

In the embodiment shown in Figure 5, two collimators 14, 14 'are provided. However, it is also possible to use a collimator with a concave mirror of such size that the image of the visual sample is obtained simultaneously for both beam paths and thus for both eyes.

With the device shown in Figure 5, the binocular refraction check is possible. The partially transmissive mirrors 28, 28 ', which in their arrangement and function correspond to the partially transparent mirror 12, are arranged rotatable about vertical axes 30, 30'. By twisting the same about the vertical axis, any convergence and divergence positions of the pair of eyes can be produced. These settings correspond to prism effects. Thus, a heterophoria test can be performed without prism switching. This not only has the advantage of simplifying the refraction, but the observation is not disturbed by the fringing and other aberrations of a preamble vorzuschaltenden otherwise.

The pivoting of the semitransparent mirrors 28, 28 'also allows the free-standing implementation of Nahbrillenbestimmung without upstream of prisms or other elements. The required convergence position is indicated by turning the two mirrors 28, 28 'in front of the eyes. The accommodation results from adjusting the displaceable prisms 46, 46 '. The near test is thus not fixed to a specific observation distance but rather can be done at any near distance.

In the embodiment shown, the semitransparent mirrors 28, 28 'are additionally arranged to be rotatable about their vertical axes 30, 30' as well as by means of a cardan suspension in addition to a horizontal axis. As a result, not only is a heterophoria test possible with regard to the lateral deviation but also with regard to any height deviation of the eye axes.

In the above-described embodiments, the change of the optical interval between the first and second optical elements 3, 4; In principle, it is also possible to dispense with the deflecting prisms 6, 46 and, instead, to arrange the lenses one behind the other and to make them movable relative to one another. However, this has constructive disadvantages with regard to the device length and the problem that the position of the exit pupil or the aperture diaphragm is not constant.

Also in the embodiment shown in Fig. 5, enlargement of the measuring range is possible by arranging lenses in the same with the exit pupil 11 which coincides with the entrance pupil of the downstream spherical system and with the focal point of the lens 3.

The displacement of the prisms 6, 6 ¹ , 46, 46 'can in principle be effected by means of manual displacement, wherein the corresponding correction value can be read off via a correspondingly calibrated scale from the position of the prism and from the rotational position of the lenses 18, 19. As shown in Figures 1 and 5, the prisms 6, 6 ', 46, 46' are adjusted via a carriage 36, 40 and a motor 35, 39. Depending on the position, an output signal from the motor is sent via corresponding lines to a computer 33, which determines the corresponding diopter values as a function of the position of the prisms and displays them via a display 34. In the same way can be supplied via a corresponding line and the Drehstellüng the lenses 18, 19 corresponding signal, so that the

Axis position of the display can be displayed. Of course, both symmetrical beam paths 37, 38 have corresponding drives and signal lines. For simplicity, however, these were only shown in the beam path 37. In addition, the angular position of the mirror 28, 28 'can be transmitted via corresponding lines to the computer, so that a corresponding program of this can also indicate a possibly existing prismatic correction required. In the embodiment according to FIG. 3, no motor drive is shown. However, this can be provided in the same way as in the embodiment according to FIG. 1 or according to FIG.

The embodiment shown in Figure 6 corresponds in its basic structure to the apparatus shown in Figure 1, wherein each corresponding parts are designated by the same reference numerals.

In the aperture diaphragm 10, a STOKES'sehe cylindrical lens 16 is arranged. In this STOKES 'cylindrical lens, which consists of two individual oppositely identical cylindrical lenses, a spherical effect is additionally produced in a known manner when setting a cylinder effect. To compensate for this spherical component thus formed, the STOKES'sehe cylindrical lens 16 and the lens 3 are mechanically coupled together so that they are together about a same path parallel to the optical axis 8 in the direction of arrow 53 back and forth. For this purpose, the lenses are mounted in not shown sockets, which are fastened by a displacement device, not shown.

As in the case of the apparatus shown in FIG. 1, the spherical correction value is first determined by pushing the prism 6 back and forth. Subsequently, the cylindrical value is determined by means of STOKES 'cylindrical lens 16. If, for example, a negative cylinder effect is set, the result is inevitably a positive spherical component of half the amount of the cylinder effect. To compensate for the same STOKES'sehe cylindrical lens 16 and the lens 3 are now moved in the direction of the prism 6 by a corresponding path. By shortening the light path between the lenses 3 and 4, the positive spherical component is compensated. The simultaneous shifting of STOKES 'cylindrical lens 16 is required so that it always remains in the aperture diaphragm 10.

As can be seen from FIG. 6, the cylinder value resulting from the adjustment of the STOKES 'cylindrical lens and the axis of the adjusted astigmatic value resulting from the angular position of the STOKES' cylindrical lens and a possible displacement of the STOKES 'cylindrical lens 16 together with the lens 3 is given via a corresponding line to the computer 33, which displays the resulting correction values on the display 34.

In principle, it would also be possible to displace the prism 6 or even the lens 4 in order to compensate for the resulting spherical component, thereby rendering the displacement of the STOKES cylindrical lens superfluous. A displacement of the lens 4 would, however, change the location of the exit pupil, which is undesirable. A displacement of the prism 6 would make the reading of the spherical

see correction values difficult because a conversion would be necessary. With the embodiment shown in FIG. 6, the position of the prism 6 gives a clear measure of the spherical correction value.

The embodiment shown in FIG. 7 corresponds in part to the construction shown in FIG. 5, wherein corresponding elements are provided with the same reference numerals. The two beam paths are formed symmetrically to each other, so that in turn is taken to simplify only one of the beam paths Eezug. A visual sample 13 is imaged infinity via a collimator 14 and a mirror 15. As in the embodiment in FIG. 5, a first optical element 3, a second optical element 4 and a prism 46 are provided in the beam path. The arrangement of these optical elements and all other parts is provided in the same manner as in the embodiment shown in Figure 5. The second optical element 4 is again a lens, while the first optical element in this embodiment is composed of two equal cylindrical lenses collecting action 300, 301 whose axes form a fixed angle of 90 ° with each other. The two lenses 300, 301 are as close as possible to each other and arranged at the same location as the lens 3 in Figure 5. Thus, the two cylindrical lenses 300, 301 overall have a spherical effect. The two cylindrical lenses 300, 301 are individually or jointly displaceable relative to one another by a device (not shown) along the optical axis. If the lens 301 is displaced toward the prism, then a negative astigmatic effect arises (minus cylinder). If the lens is moved away from the prism, the result is a positive one

24 32

astigmatic effect (plus cylinder). The size of the shift depends on the strength of the cylindrical lenses.

When using the device, the first and second optisehe element 3, 4 and the prism 46 are again set so that the focal points Fi and F ₄ coincide as in Figure 1, By means of displacement of the prism 46, the spherical correction is determined, which depends on the location of the prism 46 on the display 34 can be read. Subsequently, depending on the preferred refraction method, operating on either minus or plus cylinders, the cylindrical lens 301 is moved away from the prism 46 away from the prism 46 or the cylindrical lens 300 until any astigmatism that may be present is detected.

The displacement of the lenses is supplied to the computer 33 via a signal line, so that the determined astigmatic value can be read on the display 34. The cylindrical lenses 300, 301 are mounted in a holder, not shown, so that they are rotatable relative to each other rotatable together about the optical axis, so that the set by the displacement cylinder is rotatable to the axis of vision corresponding axis position. The rotational position is supplied to the computer 33 via the signal line, so that the axial position of the cylinder on the display 34 can be read.

In the above-described displacement of either the cylindrical lens 301 or the cylindrical lens 300 alone, a pure astigmatic portion without additional spherical portion, so that no additional correction is required unlike the embodiment shown in Figure 6. If, on the other hand, the two cylindrical lenses 300, 301 are displaced synchronously relative to one another, this results

As in the case of the example shown in FIG. 6, in STOKES 'cylindrical lens, a spherical component which would have to be compensated for by displacing the light path between the first optical element 3 and the second optical element 4.

As in the exemplary embodiments described above, the cylindrical lenses 300, 301 according to the invention are also designed in the embodiment described with reference to FIG. 1 as plane-cylindrical lenses which have a zero effect in one vertex and a cylinder effect in the vertex perpendicular thereto.

As can be seen from the above, the embodiment shown in FIG. 7 is very particularly advantageous since the construction is considerably simpler than in the embodiment shown in FIG. Since there is no image rotation in the setting of the astigmatism, in particular, the use of additional DOVE prisms is not required.

As stated above, the location at which the eye to be examined must be located depends on the focal length of the second optical element 4, since the eye pupil should be at the location of the exit pupil or at a distance corresponding thereto from the apex distance. As the measuring range increases, the focal length of the lens 4 becomes shorter. Since the partially transparent mirror 28 must still be arranged between the lens 4 and the exit pupil, it may happen that the eye has to approach undesirably close to the mirror 28. In order to increase this distance, it is expedient, according to the embodiment shown in FIG. 8, between the lens 4 and the semitransparent mirror 12, that shown in FIG.

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Embodiment or the lens 4 and the semitransparent mirror 28 of the embodiment shown in Figure 7 an afocal system of two converging lenses 50, 51 are arranged. The two converging lenses have the same focal length. The lens 50 is disposed in the image-side focal plane F \ , and the object-side focal point F ₅ - coincides with the image-side focal point Fl _Q. This produces the exit pupil 11 of the overall system in the double focal length 2f _{5Q of} the _converging lens 51. The working distance thereby increases as a function of the choice of the focal lengths of the lenses 50, 51.

Claims (19)

invention claim 1. A device for subjective refraction determination, characterized by an optotypes in its image-side focal plane imaging ^ first optical element (3) and this in the optical beam path downstream, the optotypes to be examined eye (7) out towards imaging second optical element (4), wherein the distance of the dingseitigen focal point of the second element (4) from the image-side focal point of the first element "(3) is variable. 2. Apparatus according to item 1, characterized in that a distance change causing the third optical element (6) is arranged in the optical beam path between the first and the second optical element (3, 4). 3. Apparatus according to item 2, characterized in that between the second optical element and the exit pupil of the system, a splitter mirror is arranged inclined at an angle to the optical axis. 4. Apparatus according to item 2 or 3, characterized in that the first and the second optical element with approximately coincident main planes are arranged adjacent to each other and the third optical element from the first 5 optical element coming rays to the second optical element deflects out. 5. Device according to one of the items 1 to 4, characterized in that the first and second optical element are cylindrical lenses. 6. Apparatus according to item 5, characterized in that the cylindrical lenses are coupled together so that the axes of their main sections are parallel to each other in a rotational position and upon rotation of a cylindrical lens, the second rotates so that the position of the axes of the main sections opposite to each other. 7. Device according to one of the points -j J ₃ ^ ₅ ß _f characterized in that in the optical beam path to the second optical element, a further system according to one of claims 1 to 6 is arranged. 8. Apparatus according to item 7, characterized in that the entrance pupil of the second system coincides with the exit pupil of the first system. 9. Device according to point η or 8, characterized in that the optical elements in the first system are cylindrical lenses and in the second system are spherical lenses. 10. Apparatus according to any of items 3 to 9, characterized in that the divider mirror is pivotally mounted about a vertical axis. 11. Apparatus according to item 1, characterized in that the first or second optical element of two cylindrical lenses (300, 301) is formed, which are arranged relative to each other on the common optical axis displaceable. 12. Apparatus according to item 11, characterized in that the two cylindrical lenses (300, 301) are rotatably mounted together in a fixed rotational position about the optical axis. 13. Apparatus according to item 11 or 12, characterized in that the axes of the cylindrical lenses (300, 301) are offset by 90 ° from each other. 14. Apparatus according to item 1, characterized in that in the aperture of the optical system thus formed a STOKES'sche cylindrical lens (16) is arranged, which is so coupled to the first, second or third optical element (3, 4, 5) in that the light path between the first and the second optical element (3, 4) can be changed when adjusting a cylinder value by means of the STORES 'cylindrical lens (16) in order to compensate for the spherical component which arises in the process. 15. Apparatus according to item 14, characterized in that the STOKES'sche cylinder lens (16) and the first optical element (3) in dependence on the setting of STOKES ¹ see cylindrical lens (16) are displaceable together on the optical axis. 16. An apparatus according to any one of items 1 to 15, characterized in that on the image side of the second optical element (4) an afocal system of two lenses (50, 51) is provided 224 3 is, wherein the second optical element (4) facing lens (50) is arranged in the image-side focal plane (Fl). 17. Apparatus according to any of items 5 to 16, characterized in that the cylindrical lenses are Planzylinderlinsen. 18. Apparatus according to any one of items 1 to 17, characterized in that for binocular refraction determination in addition to the optical system according to one of claims 1 to 17, a second identically formed optical system is provided. 19. Apparatus according to any one of items 1 to 18, characterized in that the housing surrounding the optical elements (2) has a support which is designed so adjustable that the eye (7) of the adjoining head of the subject a predetermined vertex distance of having the exit pupil of the entire system. ffierziULjSeiten drawings