CH698355B1 - Ophthalmological apparatus and method for determining a position of an eye of a patient. - Google Patents

Abstract

The invention relates to an ophthalmological apparatus (1) for optical and photometric examinations on an eye (2) of a patient, comprising an observation device (3) for observing an eye part (4, 400) to be examined, in particular an ocular fundus (4, 400), in a prescribable recording position (5) of the eye (2), and a measuring device (6) with a measuring sensor (61, 61a, 61b) for determining a position (50) and / or an orientation (51) of the eye (2) with respect to the observation device (3). According to the invention, with the measuring sensor (61, 61a, 61b) an intensity and / or a direction of a measurement signal (8th, 70th, 700) reflected on a surface (7, 70, 700), in particular on the cornea (7, 700) of the eye (2) , 8a, 8b), so that the position (50) and / or the orientation (51) of the eye (2) with respect to the observation device (3) can be determined automatically with the aid of the measuring sensor (61). The invention further relates to a method for determining a position of an eye (2) of a patient in relation to an observation device (3) by means of an ophthalmological device (1).

Description

The invention relates to an ophthalmological apparatus for optical and photometric examinations on an eye of a patient and a method for determining a position of an eye of a patient with respect to an observation device of an ophthalmological apparatus according to the preamble of the independent claims 1 and 8.

Known ophthalmic devices have, inter alia, the disadvantage that it is almost impossible in repeated, successive examinations and measurements for the doctor, the device with respect to the center of curvature of the Corneavorderfläche or the visual axis of the patient's eye for location and location always exactly the same ie reproducible, align. However, this is necessary if examination values from time-staggered examinations are to be comparable. As an example of such a device, reference is made to CH 662 261. For an eye examination with such a device, the head of a patient is fixed on a fixation device. In turn, the patient fixes the eye to be examined by directing it to a fixation mark inserted in the beam path of the microscope. The device which can be adjusted in the direction of the three spatial axes is set by the observer, ie by the ophthalmologist or the optician, relative to the patient's eye so that it perceives a sharp image of the fundus or of its location to be examined. The observer, however, lacks the possibility, in later investigations, of setting up the device on the same observation axis as in the preceding one. This results in subsequent investigations u.a. other light reflections than in the previous one, which falsifies the brightness measurement on the examined fundus parts of the eye and renders the measured values useless for lack of reproducibility. One of the main reasons for the poor reproducibility of the measurement is that a light signal required for carrying out the adjustment must run through the eye through the eye to the back of the eye and back to the observer.

A comparatively significant improvement has therefore been proposed some time ago in EP-A-0 608 516, which teaches an optical device with which to reproduce the optics of a microscope or a camera for imaging the retina relative to a patient's eye can position.

Both the distance between the eye and the optics and the optical axes (direction) can be accurately positioned so that accurate repositioning is possible. In this procedure, a cone of light is irradiated on the cornea, with the apex in the eye. Since the surface of the cornea is spherical, a part of the light is - if the distance is right - reflected back as a beam with a constant cross section. If the distance is too short or too long, the reflected light beam widens or narrows. If the optical axis does not hit the center of the cornea, the direction in which the reflected light is reflected changes. When the optical system is accurately and repeatably positioned in front of the eye, the light reflected from the blood vessels of the retina can be quantitatively and reproducibly evaluated, for example for the determination of blood values.

Instead of using such a method in humans for reproducible positioning of the eyes, it can also be used, for example, in domestic animals. Thus, in the context of this application, the patient should also be understood to mean a pet or another animal with biologically comparable eyes.

For a better understanding of the present invention, the state of the art will be explained in more detail below with reference to FIGS. 1 and 2, which schematically show an ophthalmological device or a field of view with eyepiece according to EP-A-0 608 516 ,

The device of EP-A 0 608 516 according to FIG. 1 serves for the optical or photometric examination on a patient's eye 23. It has an illumination device 11, 12, 13 and an observation device 1, 2, 3, 9 for the fundus. In order to be able to align the optical axis of the observation device always on the same from the center of curvature of the Corneavorderfläche outgoing radial beam, the observation device 1, 2, 3, 9 a positive auxiliary lens 20 is vorgesetzt. In an intermediate image plane 16, in the region of its focal plane facing away from the patient's eye 23, the latter generates a real intermediate image of the eye part to be examined for the observation device 1, 2, 3, 9. Further, on the side of the intermediate image plane 16 facing away from the attachment lens 20, a luminous mark 22 is present near or on the optical axis. The mentioned elements 1, 2, 3, 9; 20; 11, 12, 13 are in their entirety by an operator of the device before the patient's eye 23 aligned and centered, that at the same time in the intermediate image plane 16 a sharp image of the eye to be examined or the section of the retina to be examined arises and at a defined, in the observation device 1, 2, 3, 9 visible location of the intermediate image plane 16 using the front surface of the cornea of the patient's eye 23 in terms of a spherical mirror a sharp image of the luminous mark 27 appears.

The device has as a viewing device a horizontally arranged 10 to 20-fold magnifying monocular microscope with a lens 1 and an eyepiece 2. The lens V is limited by a diaphragm 3 in the opening. In a plane 4 of the intermediate image in front of the eyepiece 2, a reticle 5 is arranged, whose frame delimits the field of view of the microscope and which marks two pixels by two crosshairs 6 in a suitable horizontal distance. Between the lens 1 and the reticle 5, a beam splitter cube 7 is inserted, which reflects off a part of the light reflected on the ocular fundus 8 laterally to an image plane 9 and makes it usable for measurement purposes.

In the lateral image plane 9 oriented at right angles to the plane of the drawing, two spaced-apart photodiodes 10 with a small measuring surface are mounted in such a way that their locations correspond exactly to the pixels marked by the crosshairs 6 (FIG. 2) of the reticle 5. In Fig. 1, the two photodiodes 10 are consecutive. Both diodes are visible but appear congruent.

The illumination device 11, 12, 13 has as light source an incandescent or halogen lamp 11 with a small incandescent body, a condenser 12 and an achromatic projection lens 13. Installed in the illumination device are further a filter diaphragm 14 and an aperture lens 13 which is provided with the projection lens 15.

The illumination device is preferably arranged so that its optical axis intersects the optical axis of the microscope in its intermediate image plane 16 at an angle α. Expediently, the illumination ensues from above via a surface mirror 17 fixedly arranged below the microscope axis, so that the light is incident from below at the angle α relative to the optical axis of the microscope. The inclined by the angle α incidence direction of the light and an appropriate dimensioning of the aperture 3 and 15 serve to keep out disturbing reflections caused by reflections on the surfaces of the refractive media, the microscope beam path and in particular the measuring beam path. The optics of the illumination device is designed so that the projection lens 13 images the special filter diaphragm 14 in the intermediate image plane 16. The illuminated field 18 (FIG. 2) can be limited in size by a light-impermeable coating vapor-deposited on the filter screen 14 or by the formation of the filter screen 14. Projected into the intermediate image plane 16, it should have a rectangular horizontal extension. Within the illuminated field, a filter pad is attached, which in the manner of an edge filter (for example, a long-pass filter) red light of the wavelength of about 600 nanometers and longer lets through (analog Wrattenfilter No. 25). However, this filter coating does not cover the entire illuminated field 18, but leaves around the designated with the crosshairs 6 of the reticle 5 pixels each a small circular zone 19 open to the passage of "white" light. Its purpose is not to over-dazzle the patient, but nevertheless to allow the examiner to orient himself.

In the extension of the optical axis of the microscope on the intermediate image plane 16 addition, an aspheric positive lens 20 is arranged in the manner of "ophthalmoscopy lenses for indirect ophthalmoscopy" such that their rear (microscope side) focal point primarily in or near the intermediate image plane 16, but by means of a degree guide 21 in the axial direction can also be moved by a few millimeters in both directions.

In the intermediate image plane 16 a perpendicular to the microscope axis two-dimensionally movable fixation mark 22 is also attached, which forms a fixation point for a patient's eye 23.

The device described is supported by a symbolically illustrated resting on a device table instrument base 24 and aligned with this in front of the eye of the patient three-dimensionally in the direction of the X, Y and Z spatial axes.

The signals of the two measuring diodes 10 are processed by calculation in a separate evaluation unit 25 and the result is displayed digitally.

In the following, the functions or the interaction of the previously described elements of the known from EP-A-0608 516 ophthalmic device will be briefly described.

Prior to the examination, the pupil is dilated to the patient. The examiner adjusts the eyepiece 2 of the microscope for his own eye 26 without accommodation on the built-in reticle 5. As usual with such examination devices, the sitting patient supports his head with chin and forehead on a headgear. By the examiner, the device is aligned by means of the adjustment of the instrument base 24 so that the front lens 20 comes to frontally a few millimeters distance in front of the eye 23 of the patient to stand. With reasonably well centered alignment, the ocular fundus 8 is already visible. Depending on whether the patient has a refractive anomaly, the auxiliary lens 20 is to be displaced somewhat in the direction of the optical axis. In Miopie shows the direction of displacement away from the patient's eye, in hyperopia towards this. The setting is correct if the examiner sees the retina sharply or if it is in focus. At the same time it is ensured that the patient in the intermediate image plane 16 can perceive the fixation point of the adjustably arranged fixation mark 22 sharply and can follow it when it is brought to a different location by the examiner. In this way, it is easily possible to align the device and the patient's eye 23 in such a way that the retinal sites preferably selected by the examiner are matched with the measurement points indicated by the tick marks. By means of the photodiodes 10, the light reflected from the selected retinal sites can now be measured, evaluated with the evaluation device 25, and the measured value (s) displayed. The evaluation device 25 forms u.a. the quotient of the brightness values determined by the two photodiodes 10 by always taking the higher value as a dividend and the lower (if it is not equal to zero) as a divisor, and displays it on a display. This quotient is a measure of the contrast transmission capability of the optical media of the patient's eye.

A very important prerequisite to obtain exactly reproducible measurement results, however, is not yet satisfied with the described elements and the specified working method. This fact will be discussed in detail below.

For the sake of simplicity, the following explanations relate to an emmetropic patient's eye 23. When set to the latter prevails between the eye 23 and the front lens 20 parallel beam path. However, this has the consequence that slight shifts of the device in all three spatial axes cause neither a shift nor a sharpness decrease of the image in the eyepiece. Device shifting is limited only by the use of vignetting. Depending on the depth setting takes place at a transverse movement of the device relative to the eye 23, first a decrease in brightness in the right or left part of the image. In between there is an exactly defined depth position, where the whole picture is evenly attenuated in the brightness during a transverse movement. However, both the cone of rays claimed by the observation beam path and the measuring beam path are significantly narrower than that due to e.g. extended eye pupil released space. However, different measurement results can also arise if, in the following measurements, different points of different transparency (turbidity) are irradiated in the eye media. Therefore, reproducible measurement results can only be obtained if the setting of the device also succeeds locally in the space of the eye media, i. with respect to the visual axis and the center of curvature of the corneal anterior surface, to perform exactly reproducible.

As an aid, on the one hand, the aperture 15 of the illumination device or its mirror image 27 is consulted and on the other hand, the front surface of the cornea of the patient's eye as a spherical mirror used. If, for the time being, one thinks of the patient's eye, a brightly illuminated, reduced image of the aperture 15 is generated by the attachment lens 20, slightly outside its front focal point. In the eye, this aperture image can be considered as a secondary source of light for the illumination of the retina. In the meantime, however, the illuminated field 18 of the filter screen 14, which is provided with a red filter pad, is sharply imaged with its field boundary. If now the device is aligned in front of the patient's eye 23 in such a way that the above small image of the aperture diaphragm 15 comes to rest approximately at half the distance between vertex and center of curvature of the cornea front surface, part of the light is reflected by its surface acting as a spherical mirror, namely as a parallel beam towards the front lens 20, ie in turn, an image 15 (FIG. 2) of the aperture diaphragm 15 is formed in its rear focal plane or in the intermediate image plane 16.

With appropriate centering of the device, this image 15 is visible in the microscope as a very bright sharply delimited circular image and repeatedly adjusted at repeated measurements at the same point in the field of view.

Meanwhile, this aperture image 15 is relatively bright and could interfere with the measurement beam path. To avoid this, the device is on the one hand so centered that the aperture image 15 comes to rest against the edge of the field of view 29. Conveniently, it is (as shown in Fig. 2) at the bottom when the microscope does not contain an image erecting system, and at the top when there is one. On the other hand, the intensity of the diaphragm image 15 is greatly reduced by a light-attenuating filter 30 arranged close to the intermediate image plane 16 above the optical axis. This circular filter 30 protrudes partially into the field of view of the microscope (about 1/3 of the diameter of the latter) and is perceived in the eyepiece 2 slightly out of focus. In this dark zone 30, which is delimited by two circular arcs, the diaphragm image 15 is set again and again with each new measurement (FIG. 2). This setting method is very sensitive to the spatial-spatial repeatability of the setting and allows for very reproducible measurements at the same retinal sites.

Is in the case of other applications, only a reproducible adjustability of the device with respect to the center of curvature of the cornea front surface of the patient's eye 23 required, the fixation mark 22 can also be omitted.

The device of EP-A 0 608 516 according to FIG. 1 and FIG. 2 can be built as a stand-alone unit, as well as attachable or attachable accessory to a present in virtually every ophthalmology practice slit lamp device. In combination with a very common slit lamp model, it is possible to equip the slit lighting device with the described red filter, thus eliminating an integrated lighting device. In this case, the deflection mirror 17 is already available.

Instead of the data acquisition device 10, 25 shown, a CCD camera and the like could also come with an automatic evaluation device which selectively performs, evaluates and displays the measurement at the two most important pixels. Another possibility is a photographic recording of the respectively examined retinal zone together with a marking of the measuring points.

The above-described apparatus according to EP-A-0 608 516 thus has significant progress, especially with respect to the reproducibility, in comparison with the previously known ophthalmic devices, as disclosed, for example, in the above-cited CH 662 261 the settings of the device in successive measurements or taking pictures of the fundus.

However, a disadvantage of the device according to EP-A-0 608 516 is, inter alia, that the complexity of the adjustment of the device is relatively high and requires a very high level of skill of the operator, so for example the ophthalmologist or the optician. This means that the setting of the device takes a certain amount of time, which at the expense of the effectiveness of the work and on the other hand burden the patient unnecessarily long. One of the main drawbacks is that in the case of slight mispositioning, there is no corresponding feedback in which direction to correct. Apart from the clear input «wrong», there is no correction parameter. In particular, at this point, the present invention should begin.

Since the operator must decide on the basis of their own subjective perception when the right setting of the device is found, the achievable measurement accuracy is limited in some way alone. This is all the more true when successive or different measurements are made by two different persons, who will naturally always have a slightly different subjective sense of vision, so that two attitudes which each judge two different persons as optimal, as a rule, are not exactly identical be, which can lead to slightly different measurement results on the same patient's eye.

Based on this prior art, it is therefore an object of the invention to further improve the reproducibility of the settings of an ophthalmological device to objectify the finding of the optimal settings, that is, to decouple from the subjective perception of the serving person, said at the same time the adjustment of the device should be significantly accelerated and simplified for the operator. In particular, a manual adjustment by the operator should be avoided as completely as possible.

The objects of this invention solving these objects are characterized by the features of independent claims 1 and 8.

The dependent claims relate to particularly advantageous embodiments of the invention.

The invention thus relates to an ophthalmological apparatus for optical and photometric examinations on an eye of a patient, comprising an observation device for observing an eye part to be examined, in particular an ocular fundus, in a prescribable recording position of the eye, and a measuring device with a measuring sensor for determination a position and / or an orientation of the eye with respect to the observation device. According to the invention, an intensity and / or a direction of a measurement signal reflected on a surface, in particular on the cornea of the eye, can be measured with the measurement sensor so that the position and / or orientation of the eye with respect to the observation device can be automatically determined with the aid of the measurement sensor ,

It is thus essential for the invention that a measuring sensor is provided for measuring an intensity and / or a direction of a measuring signal reflected on a surface, in particular on the cornea of the eye, so that the measuring signal can be measured with the aid of the measuring sensor and From this measurement result, the position and the orientation of the eye with respect to the observation device can be automatically determined in advance for an examination of the eye.

That is, the method is used to optically determine the position and orientation of a patient's eye to be examined. An optical or photometric examination with an opthalmic optic is performed. Positions of optically imageable elements of the eye are determined, namely by means of a) light and / or sound waves, b) at least one light or sound-registering sensor and c) sensor signals evaluating devices. The sensor is arranged in front of, inside or behind the ophthalmic optics. Based on the determined measured values, data for the position and orientation of the patient's eye are calculated. As optically imageable elements are selected those which are visible outside the pupil on the eye. Simultaneously with the determination of an eye distance, i. the distance of the eye from the optic, is acted on the patient by means of an optical stimulus in the form of a target target, in particular a luminous brand, in order to provide the patient for accommodation, i. Adjustment of the optical focus on the retina, and thus to set a target distance. A total optical distance of the retina is determined from the eye distance and the optical target distance.

In contrast to the direct imaging of the retina or a projected onto the retina pattern, as implemented in refractometers (see "An automatic objective optometer", Pol K.A. and Kerr K.E., Arch. Ophthal.

93 (3), 225-231 (1975); "Automatic infrared refractors: A comparative study," Wesemann W. and Rassow B., Am. J. Optom. Physiol. Opt. 64 (8), 627-638 (1987)), the absolute position and orientation of the eye should be determined here. At the same time, the representation of a luminous target and a defined position, the optical distance of the retina is to be determined indirectly by the eye distance, i. the distance of the eye from the optics, and the total optical distance from the eye distance and the optical target distance is determined. Instead of a focus on the retina, the eye distance is measured and the focus of the eye specified.

It is thus determined by the inventive method, the optical distance of the retina by means of the target target indirectly. The optical distance, in contrast to the corresponding geometric distance, is the distance of an image that appears when viewing an imaged object (e.g., target target). Optical elements or optically active zones influence the optical distance. It can also be infinite, zero, or negative.

The target target or target is a luminous object or projected luminous reference that appears to the patient at a predetermined optical distance.

The meaning of the terms "optical distance" or "geometric distance", as well as the meaning of the "target targets", referred to in the context of this application as a "fixation mark" will be further defined and explained below in connection with the description of the figures ,

With the device according to the invention or the method according to the invention, the signal backscattered by the cornea is used to automatically track the recording system with a detector or to take a picture when the patient's eye is correctly positioned. As detectors, various known devices can be used.

In contrast to other methods, as used in refractometers, the lens of the eye itself is not taken into account. Rather, the patient is "forced" by a highlighter to accom- modate his eye lens at a certain distance (usually to "infinity").

Since the reflex is used on the cornea, more light is available than in methods in which the retinal focus is determined directly; On the one hand, the light does not have to go in and out through the narrow pupil, and on the other hand it does not have to be reflected by the dark retina with a high loss of light.

Advantages of the invention are listed below: Secondarily focusing on a structure in front of the retina eliminates the need to record light reflected from the retina. As a result, the eye is less irritated by the lighting. There is no need to perform structure recognition, which makes the method very fast. A quadrant measurement of the light distribution can be done in microseconds. Two-dimensional scattering patterns can be detected in a few milliseconds. With this, autofocus and alignment can be performed without stabilization, that is, neither the patient nor the device needs to be fixed. The detection requires little computational effort. The performance of the CPU is available for image processing and not for guiding the optics. As a result, more powerful image processing algorithms can be realized. Systems with a "low power mode" can also be implemented, which only have to calculate when an image is present. Not only can the distance of the fundus (retina) be determined, but also its position. This allows systems or patients to be guided. The "capture areas" of these methods vary considerably, that is, the systems are capable of locating the eye as long as it is in a certain area, the pick-up area of the optic. Instead of an integrated optics, as they exist in refractometers, which must cover a very large zoom and focal range, three simple optical components are used to implement the invention, all of which must be very little or not at all flexible. This eliminates or greatly reduces the moving parts. <tb> a) <sep> Target is or can be faded in at fixed optical distance. <tb> b) <sep> Focus of the recording system can be fixed or on retinal distance + target distance - distance optics to target. <tb> c) <sep> Distance measurement needs no focus, depending on the design. Target lighting, focusing and shooting can be active at the same time and need not be performed sequentially, allowing for faster build-up and preventing artifacts.

In an ophthalmological device according to the present invention, the observation device preferably comprises a lighting device for illuminating the eye part to be examined. Incidentally, the observation device as such can moreover have several, preferably all, features of the ophthalomoliginous device according to EP 0 608 516 described in detail above with reference to FIGS. 1 and 2.

That is, the present invention is a development of the device according to EP 0608 516, in which additionally a measuring device is provided with a measuring sensor, so that with the measuring sensor, an intensity and / or direction of a on a surface, in particular at Cornea of the eye, reflected measurement signal is measured and with the help of the measuring sensor, the position and / or orientation of the eye with respect to the observation device is automatically determined.

In this case, an electronic evaluation unit is provided which is signal-connected to the measuring device and an adjusting means, for example with an instrument base 24 according to FIG. 1 for the automatic adjustment of the observation device, so that using the reflected on the cornea of the eye measurement signal the Observation device with respect to the position and / or orientation of the eye is automatically adjustable in position and orientation.

For generating the measurement signal, at least one signal generator is preferably provided, wherein the signal generator is an optical signal transmitter and / or an acoustic signal generator and / or wherein the illumination device can be used simultaneously for illuminating the eye part to be examined as a signal generator. The acoustic signal transmitter is preferably an ultrasound sensor, with which in particular spatially narrowly defined ultrasound beams can be generated, so that the position and / or orientation measurement can be performed by reflection on a surface of the eye with high spatial and temporal resolution.

In order to align the eye during the investigation as well as possible on the direction of observation, the spatially narrow the unavoidable eye movements and at the same time the eye to a defined distance, preferably, but not necessarily to infinity, or focus on a predetermined image plane can be placed in a predetermined viewing direction of the eye in an intermediate level a fixation mark for fixing the line of sight of the eye, and / or wherein the fixation mark can be projected by means of a projecting device in the intermediate plane.

For recording or recording of the eye to be examined, in a conventional manner, a chemical and / or electronic recording medium, in particular a photo camera, and / or a video camera, and / or a digital camera and / or a CCD camera for photographic and / or electronic recording of the eye part to be examined.

A particular advantage of the ophthalmic device according to the invention is that the determination of the position and / or orientation of the eye with respect to the observation device can be done very quickly, in particular very much in relation to the speed with which the eye is during the examination inevitably always moving. Therefore, it is possible that the measuring device of the present invention permanently measures the position and / or orientation of the eye, and as soon as the eye is in the desired position and / or orientation with respect to the observer, a photograph is automatically taken, e.g. initiated by means of the CCD camera or by means of another recording device.

In such an embodiment, therefore, the eye only needs to be roughly aligned with the observation device, possibly supported by a fixation mark already mentioned above. Respectively. the eye only needs to be brought close to the capture area; then the patient sees the fixation mark, and the aiming device triggers the admission as soon as the patient has reached the optimal position or one of the optimal positions. That Thus, an electronic evaluation unit may be provided and signal-connected with the measuring device such that a recording of the eye part to be examined by means of the electronic recording means is automatically carried out as soon as the eye is in the recording position.

The invention further relates, in addition to the ophthalmic apparatus described above, to a method for determining a position and / or an orientation of a patient's eye with respect to an observation device of an ophthalmological apparatus) for optical and photometric examinations on the eye. In this case, the eye for observing an eye part to be examined, in particular an eye fundus, placed in a predetermined recording position with respect to the observation device and a measuring device provided with a measuring sensor for determining the position and / or orientation of the eye with respect to the observation device. According to the invention, an intensity and / or a direction of a measurement signal reflected on a surface, in particular on the cornea of the eye, is measured with the measurement sensor, and the position and / or orientation of the eye with respect to the observation device is automatically determined with the aid of the measurement sensor.

As already explained above, an illumination device for illuminating the eye part to be examined is preferably provided for carrying out the method according to the invention and a signal generator is provided for generating the measurement signal, an optical signal transmitter and / or an acoustic signal transmitter being used as the signal transmitter, and / or wherein the lighting device is used as a signal generator.

To optimize the method of the present invention, a fixation mark for fixing the line of sight of the eye can be placed in a predefined viewing direction of the eye in an intermediate plane. Preferably, but not necessarily, the fixing mark is thereby projected by means of a projecting device into the intermediate plane. Of course, in special cases, a suitably configured fixing mark can also be placed directly in or next to an optical axis of the system.

For automatic alignment of the observation device on the eye to be examined, an electronic evaluation unit is provided and signal-connected with the measuring device and an adjusting means for automatic adjustment of the observation device, so that using the reflected on a surface of the eye measurement signal, the observation device with respect to Position and / or orientation of the eye can be adjusted automatically.

For recording the eye part to be examined, a chemical and / or electronic recording medium, in particular a photographic camera, and / or a video camera, and / or a digital camera and / or a CCD camera for photographic and / or electronic recording can be advantageously used become.

In an especially advantageous practice for practice an electronic evaluation unit is provided and is signal-connected to the measuring device, so that a recording of the eye to be examined by means of the electronic recording means is automatically carried out as soon as the eye has been moved to the recording position.

In practice, the eye part to be examined, for example the iris or a blood vessel on the eyeball, is imaged with a camera, the camera focusing particularly preferably with an autofocus on the eye part to be examined, and a measured value for the eye Focusing distance is used to calculate the position and / or orientation of the eye, so that successive measurements can be reproduced even better or compared and compared with each other.

Initially, it is only essential for the invention that an optical or acoustic signal emitted by a signal transmitter is reflected on a surface of the eye in such a way that it can be detected by at least one measuring sensor and from the measurement of the measuring sensor Position and / or orientation of the eye can be determined automatically with respect to the observation device.

In the most general case, neither the signal transmitter nor the measuring sensor need to be placed in an excellent position, nor must the signal transmitter and the measuring sensor be arranged in a geometrically excellent orientation or position relative to each other. Both can even be arranged to be movable manually or automatically, for example by means of a computer-controlled positioning device.

In order to be able to determine the position and / or the orientation of the eye with respect to the observation device from the measurement data acquired by the measurement sensor, the position and / or orientation of the signal generator and / or the sensor need only in the most general case at the time of the measurement To be known measuring sensor and / or the observation device, or be determined in a suitable manner known per se in the art, in order to determine the position and / or orientation of the eye with respect to the observation device automatically.

This can be done, for example, that from the position and / or orientation data of the aforementioned components of the ophthalmological device involved at the time of measurement and from the measured by the measuring sensor measurement data, the position and / or orientation of the eye with respect to the observation is calculated by a data processing system. The aid of a look-up table is also conceivable in which, for example, position and / or orientation data records and / or possible measurement results of the measuring sensor are stored, which can then be used to determine the position of the eye in relation to the direction of observation. The person skilled in the art understands how he can advantageously use the possibilities mentioned above for determining the position of the eye in relation to the observation device and possibly even improve them in a manner known per se.

In a method of the present invention which is particularly important and preferred for practice, a characteristic of a spherical mirror known per se from optics is particularly advantageously utilized or applied.

In this case, a light cone is directed to the cornea of the eye by means of the illumination device and an upstream optics, wherein the outer surface of the cornea is used as a spherical mirror. The light reflected by the cornea is focused after a second passage through the upstream optics to a reflex point, wherein the position of the reflex point for electronic data processing is measured by means of the measuring sensor and the relative position of the eye with respect to the observer is set so that the reflex point assumes a predetermined position, which corresponds to a reproducible feasible examination of the patient's eye. This special technique will be discussed more intensively below in the description of the figures and illustrated by means of examples.

In a particular embodiment, a location and / or orientation of the measurement sensor and / or the signal generator may be flexible, that is, the measurement sensor and / or the signal generator may be movable, e.g. slidable or rotatable, be arranged, and the measuring sensor and / or the signal generator can be designed with a control such that they react in the operating state to changes in position of the reflex point with search and trapping movements.

In particular, the illumination device and / or the signal generator can provide a movable measurement signal with which the reflex point can be directed to the predetermined position.

In particular, a method according to the invention thus relates to a method for optically determining the position and orientation of a patient's eye to be examined, wherein an optical or photometric examination is carried out with an opthalmological optic, positions of optically imageable elements of the eye are determined by means of a) Light and / or sound waves, b) at least one light or sound-registering sensor, which is arranged in front of, inside or behind the ophthalmic optics, and c) sensor-evaluating devices, and wherein, based on the measured values thus obtained, data for the position and orientation of the Patient eye are calculated. As optically imageable elements are selected those which are visible outside the pupil on the eye, while simultaneously with the determination of an eye distance, i. the distance of the eye from the optic to which the patient is acted by means of an optical stimulus in the form of a target, in particular a luminous brand, in order to allow the patient to accomodate, i. Adjusting the optical focus on the retina, and thus to set a target distance, wherein a total optical distance of the retina from the eye distance and the optical target distance is determined.

In a preferred embodiment, light is directed as a light beam at a predetermined angle to the eye, the light beam is generated with a light source or ambient light and a collimator, and scattered light from the eye is recorded by the sensor for subsequent evaluation.

In this case, it is possible that a sharply delimited light spot is projected onto the eye, that the location of the reflected scattered light is measured by means of the sensor, so that on the basis of these measured values the distance of the eye from a reference point can be determined and a more precise and faster position determination instead of a light spot, a plurality of such light spots can be used.

In a particular embodiment, the optically imageable elements of the eye are, in particular, the irises or blood vessels on the eyeball, which elements are imaged with a camera, and the camera with autofocus, which may be a conventional autofocus, on the elements focuses, and a focus distance reading is used to calculate the position of the patient's eye.

In particular, ultrasonic waves can be generated and received by means of at least one transducer element.

In a further embodiment, a light cone is directed to the cornea by means of a lighting device and an upstream optics, so that the outer surface of the cornea is used as a spherical mirror, wherein light reflected from the cornea after a second passage through the upstream optics on a Reflection point is focused, and the position of the reflex point for electronic data processing is measured by a sensor, and the relative position of the patient's eye is adjusted with respect to the opthalmological optics so that the reflex point assumes a predetermined position corresponding to a reproducible feasible examination of the patient's eye.

In particular, the position and orientation of the sensor, with which the reflex point is measured, be flexible and the sensor can be formed with a control such that it reacts to changes in position of the reflex point with search and capture movements, and / or the lighting device provide a movable lighting, with which the reflex point is steerable to the predetermined position.

The invention will be explained in more detail below with reference to the schematic drawing. Show it: <Tb> FIG. 1 <sep> a known ophthalmological apparatus according to EP 0 608 516; <Tb> FIG. 2 <sep> the field of view in the eyepiece of the device of Fig. 1; <Tb> FIG. 3 <sep> a patient eye to be examined with devices according to the invention for determining its position and orientation; <Tb> FIG. 4 <sep> Law of reflection on a spherical mirror; <Tb> FIG. Fig. 5 is an illustration for producing a concentrated reflex point on an optical axis in the case where the patient's eye is in an ideal position; <Tb> FIG. Figure 6 shows the illustration of Figure 5 as a longitudinal section, with the image plane extending along the optical axis; <Tb> FIG. 7a-7c <sep> offset of the reflex point for three cases for which the patient's eye has moved out of the ideal position; <Tb> FIG. 8a-8d <sep> two-part fixation mark with illuminated cross; <Tb> FIG. 9 <sep> Structure of the Fixiermarke according to Figures 8a-8d. <Tb> FIG. 10 <sep> optical design of an ophthalmic device according to the invention; <Tb> FIG. 11 <sep> simple design with slit lamp.

FIGS. 1 and 2 show a known prior art for explanation. In order to distinguish the prior art from the present invention, the reference numerals in Fig. 1 and Fig. 2 have been given an apostrophe, while the reference numerals in the other figures, all of which relate to the invention, do not carry an apostrophe. Since FIGS. 1 and 2 have already been discussed in detail at the outset, there is no need for further discussion here.

The highly schematic Fig. 3 gives two examples of how to proceed to examine a patient's eye 2 using light beams 8, 8a or 8, 8b and sensors 61, 61a and 61, 61b, respectively, to determine position and orientation. The following parts are indicated on the eye 2: the cornea (surface of the eye on which the measurement signal is reflected, in particular the cornea) 7, 70, the lens 200, the retina (retina, the eye part to be examined, in particular the fundus of the eye) 4, 400 and the dermis 7, 700. An optical or photometric examination is carried out with an opthalmic optic 1. An upstream optics 300 is disposed between the eye 2 and the ophthalmic optics 1. The upstream optics 300 may also be omitted or part of the opthalmic optics 1. An optical axis 1000 extends through the cornea 7, 70, the upstream optics 300 and the ophthalmic optics 1. The light beam 80, 80 a is projected onto the eyeballs 7, 700 (outside of the dermis 700) with a light source 62, 62 a it is reflected as a beam-shaped scattered light 8, 8a in the sensor 61, 61a. The light beam 80, 80a could also be reflected on the cornea 7, 70. Alternatively, the light beam 80, 80b emerging from a light source 62, 62b is refracted in the cornea 7, 70, whereby a light beam 8, 8b emerging from the cornea 7, 70 is measured by means of a sensor 61, 61b.

Positions of optically imageable elements of the eye 2 are determined by means of a) light and / or sound waves, b) at least one light or sound-registering sensor 61, 61a, 61b, which is arranged in front of, inside or behind the ophthalmological optics, and c) sensor signals evaluating devices. In this case, data for the position 5, 50 and orientation 5, 51 of the patient's eye 2 are calculated on the basis of the measured values obtained in this way.

According to the invention, as optically imageable elements, those are selected which are visible on the outside of the pupil. Simultaneously with the determination of an eye distance, i. the distance of the eye from the optic, as will be explained later, can be acted on the patient by means of an optical stimulus in the form of a target, in particular a luminous brand, in order to allow the patient to accomodate, i. Adjustment of the optical focus on the retina, and thus to set a target distance. A total optical distance of the retina is determined from the eye distance and the optical target distance.

In a specific embodiment of the present invention, the ophthalmic device is an optical device with which, for example, the optics of a fundus camera can be reproducibly and automatically positioned with respect to the eye. Both the distance between the eye and the optics of the fundus camera as well as the optical axes, ie the orientation, can be precisely positioned. In a particular embodiment of the invention, this is achieved by means of a cone of light which is directed onto the cornea, the cone of light tapering in the direction of the eye in such a way that the cone tip of the light cone comes to rest within the eye. Since the cornea is a substantially perfect spherical shell, a portion of the light, if the distance is right, is reflected back as a parallel beam along the optical axis.

For clarification, the well-known reflection law is sketched on a spherical mirror in Fig. 4: The spherical mirror K extends with radius r to the center M. The focal point F of the spherical mirror is located on the optical axis 1000 at a distance r / 2 from the center point M. of the spherical mirror K. If a converging light beam 80 hits the reflecting surface of the spherical mirror K in such a way that a point of convergence of the convergent light beam 80 comes to lie exactly at the focal point F within the spherical mirror K, then the converging light beam 80 becomes a parallel beam 8, reflected by the spherical mirror K parallel to the optical axis 1000. Since, as already mentioned, the cornea is a practically perfect spherical shell, a light beam 80 incident on the cornea is reflected again, as on a spherical mirror, which makes use of the present invention. It is understood that, for example, when using an ultrasonic beam instead of a light beam analogous laws apply to the reflection at the surface of the spherical mirror K.

If a distance is too short or too long such that the point of convergence of the incident light beam 80 does not come to lie at the focal point F, the reflected beam 80 is no longer parallel but either convergent or divergent. The direction of the optical axis finally determines the direction in which the reflected radiation is reflected. Thanks to this precise repositioning, the light reflected by the retina, which can also originate from another light source, can then be quantitatively evaluated during an eye examination.

The previously explained will be discussed later with reference to FIGS. 5 to 7.

According to the invention, the backscattered signal is used to automatically track with a suitable detector, for example, with an optical or acoustic sensor, which are well known to the skilled person in numerous variants, either the recording system or just at the moment a recording to do when the eye is correctly positioned. In contrast to other devices and methods, such as those used in refractometers, neither the lens nor the vitreous of the eye is used to determine the position and orientation of the eye, but only the signal reflected on the outside of the eye is evaluated loss of attenuation, absorption, refraction, and other effects that can affect a measurement signal inside the eye do not play a role in an apparatus of the present invention. Thus, in particular, more light is available, since the light does not have to enter through the narrow pupil of the eye and must escape again before it is evaluated for position determination.

Preferably, as will also be discussed in more detail later, a highlighter may be used which forces the patient's eye to acccode the eye lens to a certain distance. In many cases, for the sake of simplicity, the eye is forced to accommodate for infinite distance.

FIG. 5 schematically illustrates a situation for generating a concentrated reflex point on an optical axis in the case where the patient's eye is in an ideal position. The illustration of FIG. 6 is a longitudinal section according to FIG. 5, wherein the image plane extends along the optical axis.

FIGS. 5 and 6 provide an illustration of the previously roughly described method of how a concentrated reflex point according to EP-A-0 608 516 can be generated for the purpose of positioning the patient's eye 2. By means of a lighting device, not shown, or signal generator 62, 62 a, 62 b, the light 600 emit, and the upstream optics 300, a beam of light with rays 8, 80, 81 directed to the cornea 7, 70. The rays 81 lie on the lateral surface of the light cone.

In Fig. 5, the upstream optics 300 is symbolized in the form of a flat cylinder 300, wherein of this cylinder 300, only the rear half is shown. The outer surface of the cornea 7, 70 is used as a spherical mirror. If the cornea 7, 70 is in a position, namely the ideal position, in which an optimal image of the retina 4, 400 can be obtained, then the light reflected by the cornea 7, 70 forms a bundle of parallel rays 8, 83 second passage through the upstream optics 300, the reflected light is focused on a reflex point 2000.

In FIG. 6 (longitudinal section to FIG. 2 with an image plane extending along the optical axis 1000), dashed lines are shown which lie within the light cone or the reflected light bundles.

Starting from the device disclosed in EP-A-0 608 516, the invention according to a particular embodiment extends the known method or the known device. With the said device, the exact position of the cornea 7, 70 can be detected in front of an opthalmological optics 3 by generating a single concentrated reflection point 2000 on the optical axis 1000 (Alinierung). According to the extension of the known method or apparatus by the present invention, the scattering pattern or a part of the scattering pattern of the cornea 7, 70 is detected when there is no alination, i. the cornea 7, 70 is not perfectly positioned. In the special case of alination, the scattering pattern converges to the single reflex point 2000 described in EP-A-0 608 516.

In the case of a deviation of the cornea 7, 70 from the ideal position, an offset 2001 of the reflex point 2000 of the ideal position arises, as shown in FIGS. 7a-7c. In each case, the point directed at the reflex point 2000 is indicated by dashed lines, as is to be expected in the ideal position of the eye 2 in relation to the observation device 3.

In Fig. 7a, the eye 1 is too far away from the upstream optics 300 (and thus too far away from the observer 3 of the ophthalmic optics 1). A reflected light bundle 8, 83 narrows, and a new reflection point 2001 has a longitudinal offset to the upstream optics 300.

In Fig. 7b with the eye 2 too close, a reflected light beam 8, 83 expands, and a new reflection point 2001 has a longitudinal offset away from the upstream optics 300.

In Fig. 7c, the eye 2 is shifted transversely to the left. A reflected light beam 8, 83 generates a new reflex point 2001, which is shifted transversely to the right.

In the case of an offset, the scattering pattern can be evaluated, namely <tb> a) <sep> determine qualitatively in which direction the cornea 7, 70 deviates from the ideal position, <tb> b) <sep> in a smaller area to determine how large the offset is.

The position of the reflex point 2000 (or 2001) is measured for electronic data processing by means of the measuring sensor 61 (not shown in FIGS. 7a-7b). The relative position of the patient's eye 2 with respect to the observation device 3 of the opthalmological optics 1 and the relative position of the observation device 3 to the patient's eye 2 is adjusted so that the reflex point 2000 occupies a predetermined position corresponding to a reproducible feasible examination of the patient's eye 2.

If the illumination device 62 provides a rigid illumination, then the measurement sensor 61 with which the reflex point 2000 is measured must have a flexible design so that the position and orientation of the measurement sensor 61 can be changed. The sensor 61 must be designed with a control such that it reacts to changes in position of the reflex point 2000 with search and capture movements. Alternatively, a fixed sensor 61 is possible if the illumination device provides a movable illumination, with which the reflex point 2000 can be directed to the predetermined, the reproducible feasible examination corresponding position.

As an alternative to the mere determination of the patient position, the optical recording system can be tracked in order to follow the patient. The scattering pattern depends on the position of the patient in all three spatial axes, on the orientation of the patient and also on the structure of the illumination.

The backscattered light can be evaluated without complex image recognition, since the backscattered light always converges in exactly one point. This brings significant benefits: <tb> i) <sep> the evaluation can be extremely fast. <tb> ii) <sep> The light source can be monochromatic, polarized or modulated to make it insensitive to ambient light and noise. <tb> iii) <sep> The light source can be operated with infrared or far infrared because it does not need to be transmitted to the eye. The source does not trigger pupil reflexes in the patient. <Tb> <sep> <tb> iv) <sep> The detection system (sensors) can be made small and peripherally attached so as not to interfere with the recording optics.

When determining position 50 and orientation 51 of the patient's eye 2 to be examined, light as light beam 80, 80a or 80, 80b (see FIG. 3) can be directed onto the eye 2 at a predetermined angle. The light beam 80, 80a, 80b can be generated with a light source 60, 60a or 60, 60b or ambient light and a collimator. The scattered light 8, 8a or 8, 8b reflected by the eye 2 is recorded by the sensor 61, 61a or 61, 61b for subsequent evaluation.

A sharply delimited spot of light can be projected onto the eye. The position of the reflected scattered light is measured by means of a sensor, so that the distance of the eye from a reference point can be determined on the basis of these measured values. For a more precise and faster position determination, a plurality of such light spots can be used instead of a light spot.

The optically imageable elements of the eye, which are in particular the iris or blood vessels on the eyeball, are imaged in a particular embodiment of the invention with a camera. The camera focuses on these elements with an autofocus. A measured value for the focusing distance is used to calculate the position of the patient's eye.

Instead of light, ultrasonic waves can also be used. The ultrasound is generated and received by means of at least one transducer element. The evaluation of scattered ultrasound is equivalent to the use of light, with the advantageous exception that during the ultrasound process also run times can be evaluated.

As already mentioned, a fixation mark, often also referred to as a target mark, which is intended to stimulate the eye of the patient to focus on a specific image plane, is preferably used. In many cases, this will be the infinity level, but this is not fundamentally necessary.

In FIGS. 8a to 8d, a preferred embodiment of a fixation mark 9, 91, 92 shown schematically, which advantageously consists of two elements 91, 92 and is designed so that they the patient as "optimal" in terms of shape and Symmetry appears when the patient's eye is exactly on the optical axis of the system.

In the case of the special exemplary embodiment of a fixing mark 9, 91, 92 shown in FIGS. 8a to 8d, the fixing mark 9, 91, 92 is made in two parts and comprises a first partial mark 91 (FIG. 8a), which is of a circular, semi-transparent surface 911 and a completely transparent cross 912 is formed. Furthermore, the fixing mark 9, 91, 92 comprises a second partial mark 92 (FIG. 8b), which is formed by a likewise circular dark background 921 and a luminous cross 922. It is understood that the shape of the fixing mark 9, 91, 92 in principle is arbitrary, so not necessarily circular, and the transparent, semitransparent, the dark background and the crosses are also interchangeable with other suitable geometric shapes. In addition, the two sub-marks 91, 92 need not necessarily be the same size. The fixation also need not be arranged spatially one behind the other; they only have to appear visually different.

A possible construction and the mode of operation of the fixing mark 9, 91, 92 is sketched schematically in FIGS. 8c and 8d. The fixation mark 9, 91, 92 forms a system of the luminous cross 922 and the semitransparent surface 911. The second partial mark 92 with the luminous cross 922 is mounted with respect to the eye of the patient behind the first partial mark 91 with the transparent cross 912. The crosses are aligned on the optical axis. In Fig. 8c is a view of the fixing mark 9, 91, 92, as it results when the fixing mark 9, 91, 92 is not viewed from the optical axis. On the other hand, as shown in Fig. 8d, the crosses 912, 922 perfectly match each other when viewed from the optical axis.

FIG. 9 schematically shows a possible optical structure of the fixing mark 9, 91, 92 according to FIGS. 8a-8d.

The luminous cross 922 is fixed at the distance of the focal length f from the optical system. The semitransparent partial mark 91 is placed in front of it. The image plane of the fixing mark 9, 91, 92 is now given by the focal length f of the optical system and the position of the illuminated cross 922. Assuming the position of the front major plane (as shown to the left in Figure 9) of the system as the origin O and the system has a total focal length of f and the mark 92 is at m, then for the image plane: <tb> <sep> 1 / b = 1 / f-1 / m

In most cases, as shown in Fig. 9, one will place m straight on f so that the image plane b comes to lie at infinity.

Since the semi-transparent surface 911 is not in the desired image plane, it should be visually less conspicuous or appealing than the illuminated cross 922 so that the patient is not accommodated on the semi-transparent surface 911.

For clarification and conceptual clarification, the optical structure of an ophthalmological device according to the invention is sketched in a highly schematic representation in FIG. 10.

[0112] The "optical distance of the retina 4, 400" is the image plane in which the retina 4, 400 appears to the image sensor 3000, for example a CCD camera 3000, for receiving the retina 4, 400. From the representation of the right main plane of the ophthalmic optics, the physical distance of the retina is r, but the optical distance is O with: <tb> <sep> 1 / O = 1 / f-1 / b.

In most cases, the image sensor 3000 will lie in the focal plane of the optics, so that O is equal to infinity, which means that the retina 4, 400 in the focal plane of the cornea 7, 70 and lens 200 system lies. The purpose of defining the optical distance O of the retina 4, 400 is to be able to use a fixed focus in the recording optics so that it does not have to be set again and again.

If one knows the eye position and the optical distance to the retina is predetermined, then no further adjustments on the path of the recording optics 1, 3 to the image sensor 3000 are more necessary.

Finally, FIG. 11 shows a very simple functional structure of an ophthalmological device according to the present invention. For reasons of clarity, the devices for automatically determining the position and / or the orientation of the eye are not shown in FIG. 11.

To observe the retina 4, 400, the eye 2 of the patient is illuminated with the slit lamp L. The slit lamp L is angled away from the optical axis. As a result, the slit lamp L does not disturb the receiving path and the reflections in the eye are attenuated.

The image of the illuminated retina 4, 400 is collected and imaged by a chromatically corrected lens assembly 31. Since the retina 4, 400 is not flat, the so-called field curvature is partially compensated by an inversely distorted image. The Kuvaturlinsen 32 form the curved image plane of the achromatic 31 on the plane of the image sensor 3000 from. If one does not use an image sensor to observe the retina, but instead uses the human eye as the image sensor 3000, then the Kuvaturkompensation is unnecessary and can be omitted.

It is understood that all inventive embodiments described in this application are to be understood as exemplary only and, as described or suggested in the present application, be provided either alone or in any suitable combinations in specific embodiments of ophthamolgischer devices according to the invention so that all suitable combinations of the embodiments of apparatus and methods described in this application are also covered and covered by the present invention, as long as they are covered by the following claims.

Claims (17)

1. An ophthalmological device for optical and photometric examinations on an eye (2) of a patient, comprising an observation device (3) for observing an eye part to be examined (4, 400), in particular an ocular fundus (4, 400) in a prescribable recording position (5 ) of the eye (2), and a measuring device (6) with a measuring sensor (61) for determining a position (50) and / or an orientation (51) of the eye (2) with respect to the observation device (3), characterized in that with the measuring sensor (61) an intensity and / or a direction of a measuring signal (8, 8a, 8b) reflected on a surface (7, 70, 700), in particular on the cornea (7, 70) of the eye (2) is measurable, so that with the aid of the measuring sensor (61) the position (50) and / or the orientation (51) of the eye (2) with respect to the observation device (3) is automatically determined, wherein an electronic evaluation unit is provided which with the fair Device (6) and an adjusting means for automatically adjusting the observation device (3) is signal-connected, so that using the reflected measurement signal (8, 8a, 8b), the observation device (3) with respect to the position (50) and / or orientation (51) of the eye (2) is automatically adjustable. 2. Apparatus according to claim 1, wherein the observation device (3) comprises a lighting device for illuminating the eye part to be examined (4, 400). 3. Device according to one of claims 1 or 2, wherein a signal generator (62, 62 a, 62 b) for generating the measuring signal (8) is provided. 4. Apparatus according to claim 3, wherein the signal transmitter (62, 62a, 62b) is an optical signal transmitter (62, 62a, 62b) or an acoustic signal transmitter (62, 62a, 62b) or wherein the signal transmitter (62, 62a, 62b) the lighting device is. 5. Device according to one of the preceding claims, wherein in a predetermined direction of view of the eye (2) in a plane intermediate a Fixiermarke (9, 91, 92) for fixing the line of sight of the eye (2) is placed, or wherein the fixation mark (9, 91, 92) can be projected into the intermediate plane by means of a projecting device. 6. Device according to one of the preceding claims, wherein a chemical or electronic recording means (3000), in particular a photocamera, or in particular a video camera, in particular a digital camera or in particular a CCD camera for the photographic or electronic recording of the eye to be examined (4, 400 ) is provided. 7. Apparatus according to claim 6, wherein an electronic evaluation unit provided in such a way and with the measuring device (6) is connected, that a recording of the eye part to be examined (4, 400) by means of the electronic recording means (3000) is automatically carried out as soon as the eye ( 2) in the recording position (5). 8. A method for determining a position (50) and / or an orientation (51) of an eye (2) of a patient with respect to an observation device (3) of an ophthalmological device (1) for optical and photometric examinations on the eye (2) wherein the eye (2) for observing an eye part (4, 400) to be examined, in particular an ocular fundus (4, 400), is placed in a predetermined recording position (5) with respect to the observation device (3), and a measuring device ( 6) with a measuring sensor (61, 61a, 61b) for determining the position (50) and / or the orientation (51) of the eye (2) with respect to the observation device (3) is provided, characterized in that with the measuring sensor (61, 61a, 61b) an intensity and / or a direction of a on a surface (7, 70, 700), in particular on the cornea (7, 70) of the eye (2) reflected measuring signal (8, 8a, 8b) measured is, and with the aid of the measuring sensor (61, 61 a, 61 b), the Po position (50) and / or the orientation (51) of the eye (2) with respect to the observation device (3) is automatically determined, wherein an electronic evaluation provided and with the measuring device (6) and an adjusting means for automatic adjustment of the observation device ( 3) is signal-connected, wherein the observation device (3) is automatically adjusted with respect to the position (50) and / or the orientation (51) of the eye (2) using the reflected measurement signal (8, 8a, 8b). 9. The method according to claim 8, wherein the observation device comprises an illumination device for illuminating the eye part to be examined. 10. The method according to any one of claims 8 or 9, wherein a signal generator (62, 62a, 62b) for generating the measuring signal (8, 8a, 8b) is provided. 11. The method according to claim 10, wherein as a signal transmitter (62, 62 a, 62 b), an optical signal transmitter (62, 62 a, 62 b) or an acoustic signal transmitter (62, 62 a, 62 b) or as a signal generator (62, 62 a, 62 b) the Lighting device (3) is used. 12. The method according to any one of claims 8 to 11, wherein in a predetermined viewing direction of the eye (2) in a plane intermediate a Fixiermarke (9, 91, 92) for fixing the line of sight of the eye (2) is placed, or wherein the fixation mark ( 9, 91, 92) is projected by means of a projecting device into the intermediate plane. 13. The method according to any one of claims 8 to 12, wherein a chemical or electronic recording means (3000), in particular a photocamera, or in particular a video camera, or in particular a digital camera, in particular a CCD camera for the photographic or electronic recording of the eye to be examined ( 4, 400) is used. 14. The method of claim 13, wherein an electronic evaluation unit is provided and signal-connected to the measuring device (6), and a recording of the eye part to be examined (4, 400) by means of the electronic recording means (3000) is carried out automatically as soon as the eye (2 ) has been moved to the recording position (5). 15. The method according to any one of claims 8 to 14, wherein a light cone on a cornea (7, 70) is directed by means of the illumination device and an upstream optics (300), wherein the outer surface of the cornea (7, 70) is used as a spherical mirror , and the light reflected from the cornea (7, 70) is collimated to a reflex point (2000) after a second pass through the upstream optics (300), the position of the reflex point (2000) for electronic data processing being detected by the measuring sensor (61 , 61a, 61b) is measured and that the relative position of the eye (2) with respect to the observation device (3) is set so that the reflex point (2000) assumes a predetermined position, which corresponds to a reproducible feasible examination of the patient's eye (2). 16. The method of claim 15, wherein a position and / or orientation of the measuring sensor (61, 61a, 61b) is flexible and the measuring sensor (61, 61a, 61b) is designed with a control such that it is responsive to changes in position of the reflex point ( 2000) with search and capture movements. 17. The method according to any one of claims 15 to 16, wherein the illumination device (3) and / or the signal generator (62, 62a, 62b) provides a movable measurement signal (8, 8a, 8b), with which the reflex point (2000) on the predetermined position is directed.