DE2940519C2 - Device for subjective refraction determination - Google Patents

Description

The invention relates to a device for subjective refraction determination, with an optotype in his Image-side focal plane imaging the first optical element and a second downstream thereof optical element for mapping the optotypes to the eye to be examined, the distance of the thing-side focal point of the second element can be changed from the image-side focal point of the first element is

The determination of the ametropia of the eye, the refraction determination, can be based on objective or be done in a subjective way. The objective refraction determination is carried out with the help of optical devices as deduced from the ophthalmoscope. at Their application does not require any intellectual cooperation on the part of the test person. It becomes the refractive index of the eye each measured monocularly.

The result of the objective refraction determination is the starting value for the subsequent subjective one Test. The decisive factor for prescribing glasses or contact lenses is always the subjective result Refraction determination, as this is the only way to test the binocular functions.

From DE-PS 6 08 165 a device for the subjective refraction determination of the eye is the Known type described above, in which an astronomical telescope system with the magnification One use is found, which interacts with a Porrosystem of the second type, the first and the fourth closely spaced reflection surfaces are at an angle of 90 ° to each other and the

Mediate the transition from the direction of vision to the path perpendicular to it. The arrangement is made so that the person to be examined has the impression that they are merely looking through a pane of glass look. However, in this system the

so the entrance and exit pupils of the telescope are not more precisely one behind the other in the direction of vision, but above or next to one another. The consideration takes place through prisms. This means that the observer's eye needs to be very close to the device. One Refraction under the conditions of free vision is not possible with this device.

From DE-PS 27 860 a device for testing the focal length of the eye is known. Here it is an optometer made of two spherical convex lenses, which is an astronomical telescope forms. The refraction can be determined by changing the lens distance. Instead of of the two spherical convex lenses should also be cylindrical convex lenses or Stokes' cylinder lenses can be used. In this device is because of the generated instrument myopia clear refraction not possible. When using cylindrical convex lenses or Stokes' lenses

Cylindrical lens rotates the image with the lens rotation in a certain axis position. This prevents binocular use, since any axis positions the vision samples appear twisted in any position, which makes fusion impossible

From the prospectus of THE HERBERT OPTICAL PRECISION CO, Taunton, Somerset, Great Britain, "The Precision Refractor", 1963, a refractometer is known which uses partially transparent mirrors to make visual samples visible and to enable observation in free space. Before Eyes to be examined are provided with trial glasses-like frames with which cylindrical lenses can be adjusted and through which the test person looks. This results in a narrowing of the field of vision such as at a phoropter. A clear refraction determination is therefore not possible with this device.

The object of the invention is to create a device for subjective refraction determination, with which the refraction is possible in a particularly simple and fast way and is clear-sighted

This object is achieved by a device for subjective refraction determination which according to FIG Invention is characterized in that between the second optical element and the exit pupil a splitter mirror is arranged inclined at an angle to the optical axis.

Advantageous refinements of the invention are characterized in the subclaims.

With this device, a fast refraction is possible in terms of both spherical and astigmatic ametropia possible under conditions of free vision. At the same time the device is too for carrying out the near-glasses determination without connecting prisms or other elements suitable.

Further explanations of the invention emerge from the description of exemplary embodiments based on the figures. From the figures shows

F i g. 1 shows a first embodiment of the invention in side view;

F i g. 2 shows a partial sectional view from FIG. 1 along line 11-11;

3 shows a side view of a further embodiment the invention;

F i g. 4 shows a section along the line IV-IV in FIG. 3; and

F i g. 5 is a schematic representation of another Embodiment of the invention for binocular measurement of spherical and astigmatic ametropia.

In the case of the FIG. 1, the device 1 has 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 one another. Opposite the two lenses 3, 4 is a totally reflective optical element 6, which is a totally reflective one Prism or a totally reflective mirror system can be arranged, which from the first 3 rays emerging from the lens are reflected in the second lens 4. The third optical element 6 becomes parallel shifted to the optical axes 8, 9, the optical interval between the lenses 3, 4 changes.

The aperture stop 10, which coincides with the entrance pupil, is arranged in the object-side focal plane F ^ of the first lens 3. The exit pupil 11 (FIG. 2) of the system has a constant position for any setting of the third optical system 6 and, for each setting, lies in the image-side focal plane F 'of the second lens 4. Between the second lens 4 and the exit pupil 11 there is a semitransparent one Plane mirror \ 2 arranged, which with the optical axis 9 of the lens 4 encloses an angle of 45 °. The visual specimen 13 is viewed via a collimator 14 Device should cause.

If the third optical element 6, which will be referred to as prism 6 in the following, is set so that the image-side focal point F 'of the first lens 3 coincides with the object-side focal point F _{4 of} the second lens 4, then parallel incident rays leave the first lens 3 the system of lenses 3 and 4 is parallel again. A right-sighted eye sees a distant object clearly. This setting corresponds to the refraction value 0.0 dpt. If the prism 6 approaches the two lenses 3, 4, the rays entering the first lens parallel to the axis leave the second lens 4 divergent. With this setting, a distant object is seen sharply by a myopic eye with a corresponding refraction. The displacement of the prism in the direction of the lenses thus corresponds to myopic refraction values, there being a linear relationship between the position of the prism 6 and the extent of myopia. The size of the shift of the prism to the size of the myopia is only dependent on the focal length of the second lens 4. Conversely, shifting the prism 6 in the opposite direction, i.e. away from the two lenses 3, 4, results in the setting for clear eyes. Rays entering the system in parallel converge out of the system of the two lenses. The ametropia wedge can be read off directly by calibrating a scale indicating the position of the prism 6.

When the first optical element 3 and the second optical element 4 are designed as spherical A STOKES cylinder lens can be used to correct the astigmatism at the location of the aperture stop 10 16 be arranged. This must be used to determine the axial position of the astigmatism around the optical axis be designed to be rotatable. The values of the STOKES cylinder lens can be used directly if the two Lenses 3, 4 have the same focal length. If the two lenses have different focal lengths, a To apply the correction factor, which results from the quotient of the refractive power of the two lenses.

Instead of the described STOKES cylinder lens 16, a stationary STOKES lens can also be used Lens combination are used, the axes of which enclose a constant angle of 45 °. In order to the two components of cylinder effects of different sizes and any axis directions to adjust. Of course, the astigmatism could also be achieved by means of a normal cross cylinder can be determined, the stem cross cylinder preferably held in the plane of the aperture diaphragm should be.

Should the measuring range of the spherical power resulting from the two lenses 3 and 4 be expanded additional lenses can be arranged in or near the plane of the aperture stop 10. Her The effect corresponds directly to the correction values, provided that the lenses 3, 4 have the same focal length.

Otherwise a correction factor must be taken into account.

As has already been stated above, the exit pupil 11 lies in each setting of the prism 6 the image-side focal plane of the second lens 4. During the measurement, the pupil (main plane) of the test subject's eye 7 coincide with the exit pupil 11. Then the so called main point refraction certainly. Is the subject's pupil at a distance of 16 mm behind the Exit pupil 11 results in the correction values for a spectacle lens vertex distance of 16 mm. Of the The distance between the pupil and the exit pupil 11 is therefore identical to the vertex distance of the prescription lenses. As in Fig. 2 indicated, the device a support 17, which can be designed as a chin or forehead support, on which the head of the test subject is supported and which is movable back and forth relative to the housing so that the distance between the pupil of the Test subjects from the exit pupil 11 is adjustable.

The test person looks at the visual sample 13, which is imaged into infinity via the collimator 14, by corresponding to the viewing direction perpendicular to the plane of the drawing in FIG looks, which is arranged at an angle of 45 ° to the optical axis 9. He sees through the mirror 12 Subject the free space at the same time as the visual sample 13, which can include optotypes or test figures. on In this way, a clear refraction determination is carried out in which the patient's field of view is not is narrowed and thus disruptive effects such as instrument myopia are eliminated from the start.

As can be seen from the above, a continuous setting of the Corrective action possible by moving the prism 6 continuously. This can be used very quickly achieve spherical correction effects, with spherical deviations the full correction and with astigmatic deviations the so-called best spherical correction can be determined. The awkward one There is no need to change the glasses and the test person can, under certain circumstances, make the optimal setting himself. the The astigmatic corrective action can also be carried out continuously with the aid of the STOKES cylinder lens 16 Set from 0 to a maximum value. Again, finding the correct axis location is important as well the determination of the full correction is possible very quickly.

In the case of the in FIG. 3 are the first and second optical elements as cylindrical lenses 18,

19 trained. These are each in a version 20.21 held, which each have a ring gear on their outer circumference. The storage of the frames takes place in such a way that when rotating the socket

the mount 21 rotates an equal 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 in the in F i g. 4 is parallel to each other in the beam path, in the embodiment shown A DOVE prism 22 is arranged in front of the first cylinder lens 18. This is shown schematically via a indicated mechanical coupling 24 so rotatably arranged in the beam path that its base 23 always is aligned parallel to the axis 25 of the first cylindrical lens 18 Otherwise, correct in this embodiment the third optical element 6, the mirror 15, the visual sample 13 imaged via the collimator 14 and those arranged in the object-side focal length of the effective main section of the cylindrical lens 18 Aperture diaphragm and the entry pupil that coincides with it with regard to arrangement and effect those in Fig. 1 and are therefore denoted by the same reference numerals. The exit pupil 11 lies again independent of the position of the third optical element 6 at the location of the image-side Focal length of the main section of the cylindrical lens 19. The observation takes place in the same way as with the first ίο Embodiment using a semi-transparent mirror 26, which is arranged in such a way that the subject is depicted at the same time as the infinite Eye test also sees the free space.

The DOVE prism 22 has the task of rotating the cylinder lenses: I8,19 To be observed each eye sample to compensate, so that the test subject has the impression of a rotationally fixed Has eye test.

For refraction, the prism 6 is set so that the image-side focal point or the focal line of the first cylinder lens 18 with the object-side focal point or the focal line of the second cylinder lens 19 coincides. Is the right-sighted observer's eye in the vicinity of the image-side focal point of the second cylindrical lens 19, in this position it can observe distant objects sharply and without distortion. If the eye to be examined has a simple myopic astigmatism, then through Moving the prism 6 in the direction of the cylindrical lenses 18, 19, the astigmatism can be corrected. By subsequently rotating the cylinder nozzles 18, 19 by means of the gears forming the mounts i! 0, 21 the correct Adisenlage is set here. Does the eye to be examined have a simple and clear one Astigmatism, the prism 6 must be adjusted away from the cylinder nozzles 18, 19.

If the DOVE prism 22 were not used, this would be the case when the cylinder nozzles were rotated watching picture rotate. It would be possible to use a fixed stick figure to test the astigmatism to use. The image of the stick figure would then each turn when the cylinder nozzles 18, 19 are rotated move to the correct position. If you want to forego the image rotation, this is done by arranging a DOVE prism or another suitable reversion element

To determine the spherical ametropia

can be used in the entrance pupil or aperture stop 10 instead of those described in the first exemplary embodiment STOKES 'cylindrical lobes with spherical lenses

wciucn.

With the embodiment described it is possible in a particularly quick and simple manner and to determine the astigmatism and its position of a defective eye with continuous adjustment. The two cylinder lenses 18, 19 are designed as plane cylinders which have the same focal length. That has the advantage that, depending on the setting of the prism 6, there is always only the cylinder effect changes in a main section, but in the main section perpendicular to it there is no visual effect The axis position of the effective main section is set in the manner described by turning the Cylindrical lenses set In this way it is achieved that the known methods and devices for Determination of the astigmatism when the astigmatic value changes, always changing spherical Effect remains unchanged and is therefore constant

Correcting the spherical power with a changed astigmatic value can be omitted.

In principle, it can be useful to use the DOVE prism 22 to be omitted and the image rotation then resulting when the cylinder lenses 18, 19 are rotated to To use refraction determination with. You then didn't need rotatable ones to find the main cuts To use test objects. However, special optotypes would then have to be used, as with normal optotypes with an oblique axis position these are shown askew.

In the case of the in FIG. 5 shown embodiment of the device according to the invention are for binocular Refraction determination two symmetrical beam paths 37, 38 are provided. Both beam paths 37, 38 have exactly the same elements, so only one will be described. The elements in the beam path 37 those in the F i g. 1 to 4 correspond, are each denoted by the same reference numerals, and the Elements in the second beam path corresponding to elements of the first beam path 37 are marked with corresponding apostrophized reference signs.

The beam path seen from the eye sample initially agrees with the beam path shown in FIG completely coincides and differs only in that instead of the semitransparent mirror 26 a fully reflective plane mirror 27 is provided. The first of the in FIG. 3 embodiment shown The corresponding part of the device is the one based on FIG. 1 and 2 Aperture stop 10, mirror 15, first lens 3, sliding prism 46, second lens 4, semi-transparent Mirror 12 and support 17 existing part of the axially symmetrical system described there downstream. The arrangement of the second part takes place in such a way that the aperture diaphragm 10 of the axially symmetrical Systems from FIG. 1 with the exit pupil 11 of the first shown in FIG. 3 matching anamorphic system coincides. With this combined system, the setting is spherical Correction values, the astigmatic correction values and the determination of the axis position on simple and fast way without adding any lenses for all values continuously below the Condition of free vision possible.

In the case of the in FIG. 5, two collimators 14, 14 'are provided. But it can a collimator with a concave mirror of such a size that the image of the Visual test for both beam paths and thus for both eyes at the same time is carried out using the method shown in FIG. 5 shown Binocular refraction check is possible.

The partially transparent mirror 28, 29, which correspond in their arrangement and function of the partially transmitting mirror 12 are rotatably arranged around vertical axes 30, 31 by Ve ^r rotate the same about the vertical axis any of convergence and divergence positions can the pair of eyes are caused. These settings correspond to prism effects. In this way, a heterophore test can be carried out without connecting prisms. This not only has the advantage of simplifying the refraction, but the observation is also not disturbed by the color fringes and other aberrations of an otherwise upstream prism.

The pivotability of the semitransparent mirror 28,29 also enables the clear-sighted implementation of the Determination of near glasses without connecting prisms 5 or other elements. The required convergence position is brought about by turning the two mirrors 28, 29 in front of the eyes. The accommodation results by adjusting the displaceable prism 46. The close examination is thus not on a specific one Fixed observation distance, but can rather be done at any close distance.

In the embodiment shown, the semitransparent mirrors 28, 29 are both around theirs vertical axes 30, 31, as well as by means of a cardanic suspension in addition to a horizontal one Axis rotatably arranged. This means that not only is a heterophore test with regard to the lateral deviation, but also possible with regard to possible height deviation of the eye axes.

In the embodiments described above, the change in the optical interval takes place between the first and the second optical element 3, 4; 18, 19 each arranged over in the beam path Prisms 6.46. In principle, it is also possible to dispense with the deflecting prisms 6, 46 and instead use the To arrange lenses one behind the other and to make them movable relative to one another. However, that has regarding the Device length constructive disadvantages and the problem that the position of the exit pupil or the aperture diaphragm is not constant.

Even with the in F i g. 5, an expansion of the measuring range is possible, in that in. the one with the exit pupil 11, the one with the entrance pupil of the downstream spherical system and coincides with the focal point of the lens 3, corresponding Lenses are arranged.

The shifting of the prisms 6, 6 ', 46, 46' can basically be done by moving them by hand, with the corresponding correction value from the position of the prism on a correspondingly calibrated scale and the axis position can be read off from the rotational position of the lens 18. As shown in Figs. 1 and 5, the prisms 6,6 ', 46,46' via a slide 36, 40 and a motor 35,39 adjusted. Depending on the position, a Output signal from the engine to a computer 33 given which, depending on the position of the Prisms the corresponding doptrial values are determined and displayed on a display 34. In the same way can Via a corresponding line also a corresponding to the rotational position of the cylinder lenses 18, 19 Signal are supplied so that the axis position can also be shown on the display. Of course Both symmetrical beam paths 37, 38 have corresponding drives and signal lines. To the For the sake of simplification, however, this was only shown in the beam path 37. In addition, the angular position the mirror 28,29 'are transmitted to the computer via appropriate lines, so that a corresponding Program this also show any prismatic correction that may be required can. In the embodiment according to FIG. 3 no motor drive is shown. However, this can be done in the same way as in the embodiment according to FIG. 1 or according to FIG. 3 may be provided.

For this purpose 3 sheets of drawings

Claims (11)

Patent claims: 1. Device for subjective refraction determination, with an optotype in its image-side focal plane imaging first optical element and a second optical element downstream of this for mapping the optotypes to the eye to be examined, with the distance of the object-side Focal point of the second element can be changed from the image-side focal point of the first element is, characterized in that between the second optical element (4,21) and the Exit pupil (11) of a splitter mirror (12, 26; 28, 29 ') inclined at an angle to the optical axis is arranged 2. Apparatus according to claim 1, characterized in that the optical elements are rotatable Cylindrical lenses (18, 19) are designed and coupled to one another in such a way that the axes of their main sections are parallel to each other in every rotational position. 3. Apparatus according to claim 2, characterized in that a in the optical beam path Reversion element (22) is provided. 4. Apparatus according to claim 3, characterized in that the reversion element (22) is a reversible prism which is coupled to the first optical element so that its base (23) is parallel to the axis of a main section of the first optical element remains aligned. 5. Apparatus according to any one of claims 1 to 4, characterized in that the optical elements are designed as cylindrical lenses (18, 19) that between the lenses a beam path in its Direction reversing third optical element (6, 6 '; 46, 46') is provided and that the cylindrical lenses are coupled to one another in such a way that the axes of their main sections are parallel to one another in a rotational position and when a cylinder lens is rotated through an angle, the second cylinder lens moves around the rotates the same angle in the opposite direction. 6. Apparatus according to any one of claims 1 to 5, characterized in that at the location of the Lenses (16) which can be switched on are provided at the entrance pupil (10). 7. Apparatus according to any one of claims 1 to 6, characterized in that the first and the second optical element form a first system that in the optical beam path after the second optical element of the first system a second system with two further optical elements which are arranged according to those of the first system, and that the entrance pupil of the second system coincides with the exit pupil (11) of the first system. 8. Apparatus according to claim 7, characterized in that the optical elements in the first system Cylindrical lenses (18, 19) and, in the second system, spherical lenses (34). 9. Apparatus according to one of claims 1 to 8, characterized in that the splitter mirror (28, 29 ') is arranged pivotably about a vertical axis. 10. Device according to one of claims 1 to 9, characterized in that the binocular In addition to the optical system according to one of Claims 1 to 8, a second refraction determination similarly designed optical system is provided 11. Device according to one of claims 1 to 10, characterized in that the housing (2) surrounding the optical elements has a support has, which is adjustable so that the eye (7) of the head resting on it Subject has a predetermined vertex distance from the exit pupil of the overall system