EP1588209A1 - Device and method for adjusting a position of an eyeglass lens relative to the position of a pupil - Google Patents

Abstract

Disclosed are a device and a method for adjusting a position of at least one eyeglass (16) lens relative to the position of a pupil of a person's (12) eye (14), which is associated with said lens. The inventive device comprises an illuminating apparatus (24) for an eye part (61) of the person (12) wearing an eyeglass frame (18) that is not yet fitted with lenses. Also provided is a camera (22) for generating an image of the eye part (61). The position of the pupil within the image is marked. The illuminating apparatus (24) encompasses at least one light source (26, 50) that operates within a wavelength range, the light (42, 52) of which is reflected by the retina (46) of the eye (14) at a high degree of reflection. The sensitivity of the camera (22) is optimized to the wavelength of the light (42) emitted by the light source (26).

Description

 Device and method for adjusting a position of an eyeglass lens relative to the position of a pupil

The invention relates to a device for adapting a position of at least one spectacle lens of a pair of glasses relative to the position of a pupil of an eye of a person assigned to the spectacle lens, with a lighting device for an eye area of the person wearing a still unglazed spectacle frame, with at least one camera for generating an image of the Around the eyes and with means for marking the position of the pupil in the image. The invention further relates to a method for adapting a position of at least one spectacle lens of a pair of glasses relative to the position of a pupil of a person's eye associated with the spectacle lens, in which an eye area of the person wearing a still unglazed spectacle frame illuminates an image of the eye area using a first light source , and the position of the pupil is marked in the image.

A device and a method of the aforementioned type are known, for example from the "Video Infral System II" of the applicant.

To adapt a pair of glasses, in particular glasses with varifocal lenses, an optician must determine the position of the customer's pupil centers with the usual head and body posture relative to the lens frame used. It must be ensured that the position of the pupil centers is determined at a point in time when the customer looks straight ahead and does not look to the side, for example because the optician is working near his eyes.

In known systems of the type mentioned at the outset, this measurement is carried out from a greater distance of, for example, five meters. The customer is put on the still unglazed frame and the eye area of the customer is measured from the distance mentioned. For this purpose, a video camera is used in known systems. The image of the customer's eye area is recorded and displayed on a computer screen. Using known cursor operations, the Opticians then mark the pupil centers in the picture, as well as certain reference lines for the position of the lens frame.

A disadvantage of the known systems is that incorrect measurements with regard to the exact position of the pupil centers can occur if the image taken in the area of the pupils is too low in contrast, with the result that the optician cannot find and mark the pupil centers exactly in the video image. This is especially true for customers with a dark iris, from whom the pupils hardly stand out. If the general lighting in the measuring room is set to be very bright, the customer also has a natural constriction of the pupils.

In a device of the type mentioned at the outset, as is known from DE 100 33 983 A1, a light source of a type not described in detail is used to illuminate the person or the spectacle frame, which is designed in a ring shape. In a further device of this type according to DE 88 12 095 Ul, a light source of a type which is also not described in more detail is used, which is shown as a conventional light bulb. Finally, FR 2 663 528 A3 describes yet another device of this type, which uses a spot lamp of the type which is likewise not described in detail for lighting.

In these known devices, light sources are also used that emit a normal light, that is, a white ambient light. The invention is therefore based on the object of developing a device and a method of the type mentioned at the outset such that the exact position of a person's pupils relative to a spectacle lens frame can also be determined in those cases in which there is only normal lighting in the measuring room result in low-contrast images of the pupils of the person.

The measurement should be able to be carried out to such an extent that the position of the pupil centers can be detected and marked by the system itself, so that manual marking of the positions by the optician with all the sources of error associated therewith is avoided.

In the case of a device of the type mentioned at the outset, this object is achieved according to the invention in that the lighting device contains at least one light source which operates in a wavelength range, the light of which is reflected by the retina of the eye with a high degree of reflection, and in that the sensitivity of the camera to the Wavelength of the light emitted by the light source is optimized.

In a method of the type mentioned at the outset, the object is achieved according to the invention in that the eye area is illuminated with at least one light from a wavelength range which is reflected by the retina of the eye with a high degree of reflection, and in that the image of the eye area with a sensitivity optimized to the wavelength of light is generated.

The object underlying the invention is completely achieved in this way.

Because the eye area of the person is illuminated with a light from the wavelength range mentioned, the retina of the eye is caused to reflect this light, so that it contrasts with the surrounding iris in the image. The use of the camera optimized for the wavelength has the advantage that particularly clear and high-contrast images can be obtained even with low light intensity.

This enables the optician to reliably detect the position of the middle of the pupil by manually marking it with a cursor. It is of particular advantage, however, if this manual operation is replaced by an automatic determination of the pupil center using conventional image processing methods. This eliminates the additional sources of error that every manual operation entails. In contrast to conventional measurements, the measurement is also so easy to carry out that it can be repeated several times in order to completely eliminate falsifying influences. These influences can e.g. a random convergence movement of the person's eyes.

A method for measuring a pupil is already known from DE 196 49 542 C2, in which the pupil is illuminated with infrared light, the use of the infrared In this case, however, (invisible) light only makes sense to exclude the nuisance of the measured patient. A reflex from the retina that would illuminate the entire pupil is not taken into account in this known arrangement. Because of the angle between the direction of illumination and the direction of observation, such a reflection does not occur either.

A system for measuring the function of pupils is known from US Pat. No. 5,150,137, in which, in one exemplary embodiment (FIG. 34), an arrangement is provided in which an infrared light-emitting diode emits a measuring light in the same optical axis along which the observation device also strikes the eye is directed. In this known system, however, only a single eye is examined at a short distance, so that the problems explained at the outset do not arise here.

In preferred embodiments of the device according to the invention, the light source emits light in the red to infrared range, the light source preferably being a light emitting diode or a gate of light emitting diodes.

These measures have the advantage that devices can be manufactured with high reliability and at low cost using commercially available components.

The lighting device expediently contains a lens in order to bundle the light emitted by the light source in the desired manner. In a further development of the invention, the camera has a plurality of color channels and image signals of the color channel which spectrally comes closest to the light emitted by the light source, in particular the red color channel, can be processed separately to form images.

This measure has the advantage that commercially available video cameras can be used which have a red channel, so that the associated image signals can be processed separately into images in which the red light remitted by the retina presents itself particularly well.

Alternatively, it is also possible to provide at least two cameras, one of which is optimized in sensitivity to the wavelength of the light emitted by the light source.

This measure also has the advantage that both images with normal light and images with the specified special light can be generated, which will be discussed further below.

In particularly preferred embodiments of the device according to the invention, the camera and the light source are oriented essentially along the same optical axis to the eye. In this case, the camera and the light source can be inclined to one another by less than 2 °, preferably less than 1 °.

This measure has the advantage that the light remitted by the retina is received particularly well in the camera can, because at least in the case of non-ametropia, the light irradiated into the eye is reflected or remitted by the retina as a narrow beam of light with little divergence.

In a practical embodiment of this exemplary embodiment, a beam splitter for coupling the light from the light source is arranged in the beam path between the camera and the eye, the light being reflected by the beam splitter in the direction of the optical axis of the camera away from the latter.

This measure has the advantage that the above-mentioned coaxial alignment of the camera on the one hand and light source light on the other hand is achieved with simple structural measures.

In a preferred development of this exemplary embodiment, the beam splitter has a reflectance of less than 50%, preferably between 8% and 40%, for the light remitted by the eye.

Although this measure is not optimal from an energetic point of view, because partial mirroring of 50% is known to be optimal, from a practical point of view the range of reflectance mentioned is preferable, however, in a further embodiment of this embodiment, the reflectance for wavelengths outside the wavelength range of the Illumination device emitted light is further reduced.

These measures have the advantage that the spectacle frame in front of the person's face can also be reliably recognized incorrect measurements that can occur in dark-skinned people can also be avoided.

Furthermore, it is preferred in the context of these exemplary embodiments if a light trap is arranged on the side of the beam splitter facing away from the light source.

This measure has the advantage that the light emitted by the light source, insofar as it is not deflected away from the camera by the beam splitter, is absorbed in a reliable manner.

In a further particularly preferred group of exemplary embodiments of the invention, additional light sources directed towards the eye area are provided outside the optical axis.

This measure has the advantage that the invention can also be used in patients with severe ametropia in whom the light of the light source radiated in the optical axis is not narrow, i.e. little divergent light bundle is reflected along the radiation axis. With the above-mentioned measures, even with such a strong ametropia (in particular myopia), a signal remitted by the retina is received in the camera, which signal remains unchanged along the optical axis mentioned.

It is particularly preferred if the additional light sources are arranged uniformly, ie in a ring-like manner, around the optical axis and are inclined to it. In the device according to the invention, as in the prior art, it is preferred if the beam path between the camera and the lighting device on the one hand and the eye on the other hand has a length of several meters, preferably between two and eight meters.

If the spatial conditions in the measuring room do not permit such dimensions, it is also preferred in a manner known per se if the beam path is folded.

In a further group of exemplary embodiments, general lighting for the eye area is provided in addition to the lighting device, and means for controlling the camera such that the camera alternatively takes a first picture only with the general lighting when the light source is switched off and a second picture with the light source switched on.

This measure has the advantage that, in separate work steps, a first, normal image of the person's eye area and, on the other hand, a second image can be recorded on which the pupils light up compared to the first image. The position of the pupils can easily be found by means of image processing in a difference image of the two images and then exactly determined in the second image with the pupils lighting up.

In the preferred variant of this exemplary embodiment, the camera takes the second image when the general lighting is switched off. This measure has the advantage that interference with the taking of the second image by the general lighting is avoided.

In this context, it is particularly preferred if the camera records the first and the second image in chronological succession, in particular if the camera is a so-called "interlaced" camera and the camera records the first and the second image as fields of a full image ,

The measures have the advantage that procedures known per se, namely so-called “interlaced” procedures, can be used.

The same advantages apply analogously to the embodiments of the method according to the invention that were explained above with reference to the exemplary embodiments of the device according to the invention.

Further advantages result from the description and the attached drawing.

It goes without saying that the features mentioned above and those yet to be explained below can be used not only in the combination indicated in each case, but also in other combinations or on their own without departing from the scope of the present invention.

Embodiments of the invention are shown in the drawing and are explained in more detail in the following description. Show it: Figure 1 shows a first embodiment of a device according to the invention, in a side view and extremely schematic.

FIG. 2 shows a modification of the exemplary embodiment according to FIG. I;

3 shows an image of a person's eye area, as can be recorded with the devices according to FIGS. 1 or 2;

FIG. 4 shows a detailed illustration to explain the mode of operation of the device according to FIG. 2;

FIG. 5 shows a further detailed illustration to explain the mode of operation of the device according to FIG. 2 in connection with FIG. 4;

FIG. 6 is a block diagram showing an electronic control for the device according to FIGS. 1 or 2;

FIG. 7 shows a pulse diagram to explain the block diagram according to FIG. 6.

In FIG. 1, 10 overall designates a device for adapting a position of at least one spectacle lens, in particular a progressive lens, of a pair of glasses relative to the position of a pupil of a person's eye associated with the spectacle lens. In Fig. 1 the person is indicated overall at 12, only one eye 14 and glasses 16 or spectacle lens frame 18 is shown.

At a distance D, which can be several meters, preferably two to eight meters, there is a recording system designated as a whole by 20.

The recording system 20 contains a camera 22, the optical axis of which is designated 23.

An illumination device 24 is provided at a right angle to the axis 23. The lighting device 24 contains a light source 26, in particular a light-emitting diode (LED), which operates in the red or infrared range. A lens 28 is assigned to the light source 26. The light source 26 is directed to a beam splitter 30, on the opposite side of which there is a light trap 32.

Finally, the recording system 20 also includes general lighting 34 with normal white light.

In FIG. 1, 40a, 40b indicate marginal rays of the light 42 which is emitted by the light source 26. The light 42 or the marginal rays 40a, 40b are reflected on the beam splitter 30 and directed onto the eye 14 of the person 12. The light 42 enters the eye 14 through an eye lens 44 and falls on the retina 46, where an image 48 is generated. A normal-sighted person 12 is a sharp image 48, while a defective person 12 creates a correspondingly blurred image, as will be explained below. The light remitted by the retina 46 is designated by 49. This in turn strikes the beam splitter 30 and partly reaches the camera 22.

The beam splitter 30 is preferably designed as a partially transparent mirror. It consists of a transparent, plane-parallel plate, e.g. made of glass, in which one side (the lower side in FIG. 1) is untreated or partially mirrored and the other side is non-reflective.

The mirror can have a degree of reflection of 50%, for example. With this choice of reflectance, most of the remitted light 49 would be directed into the camera 22. The light 42 emitted by the light source 26 is namely reflected at the mirror with the same degree of reflection, directed towards the eye 14 and remitted there by the retina 46. The returned light

49 reaches the camera 22 as the portion passing through the beam splitter 30.

From an energetic point of view, a reflectance of 50% would be optimal. From a practical point of view, however, there is a clear deviation from this and, for example, a reflectance in the order of 8% to 40% is used.

Furthermore, a mirroring is preferably selected which expediently has an even lower reflectance at the wavelengths at which the light 42 has no or only a low intensity. Lower reflectivities than those mentioned

50% are also particularly helpful because you also have the spectacle lens frame 18 in front of the face of the person 12 must detect. If the person 12 is dark-skinned, the benefit of this measure proves to be particularly great.

As has already been mentioned, the light source 26 is preferably a light-emitting diode that operates in the red or in the infrared range. Instead of a single light-emitting diode, a bundle of such diodes can alternatively be used, a corresponding honeycomb arrangement then having to be selected as the lens 28, as is known per se.

The light trap 32 only indicated in FIG. 1 has the task of absorbing the light 42 which passes through the beam splitter 30 without being reflected. A black cardboard, a sooty sheet or a surface covered with black velvet can be used as the light trap 32, for example. Such a light trap can also be designed, for example, as a so-called "black bag".

3 shows an image 60 recorded by the camera 22. An eye area 61 of the person 12 can be seen. The right and left pupils of the person 12 are identified by 62r, 621, the associated iris by 64r, 641. The center of each Iris 64r, 641 is drawn in FIG. 3 as a cross between two dash-dotted lines.

Finally, with vertical lines 66r, 661 and horizontal lines 68r, 681, reference lines of the spectacle frame 18r and 181 are also entered.

3 clearly shows that both the exact position of the center point of each iris 64r, 641 and the exact position of the eyeglass frames 18r and 181 are shown in FIG usual image processing methods can also be recognized automatically. In any case, it is possible manually to mark these points or lines in a simple manner using a cursor and to mark them in picture 60.

As a result of the selected wavelength of the light 42, the retina 46 behind the pupils 62r and 621 shines brightly, so that the pupils 62r, 621 stand out clearly from the respective iris 64r and 641, respectively. This also and especially applies when the iris 64r, 641 is relatively dark by default.

Fig. 4 shows the situation in a person 12 who is at a short distance, e.g. to position 70 is accommodated, in particular because the person 12 is short-sighted. At point 70 there is a real image of retina 46 in eye 14.

In order to be able to carry out a successful measurement in this case as well, the exemplary embodiment according to FIG. 2 is used, in which additional light sources 50a, 50b are arranged around the axis 23, in particular in the form of a ring. The marginal rays 52a, 52b shown in FIG. 2 identify the light emitted by the additional light sources 50a, 50b. This light runs towards the middle of the person's pupils. Because of the ametropia, blurred images of the additional light sources 50a, 50b form on the retina 46 of the eye 14. The intensity distributions around the geometric projection points along the marginal rays 52a, 52b are shown schematically on the partial images 72a to 72c on the right in FIG. 4. In Fig. 4 are the angles between the edge rays 52a, 52b and Axis 23 is obviously exaggerated and much larger than in reality.

As can be seen from the partial images 72a to 72c, the edges of the outer intensity distributions 72b, 72c overlap with the central intensity distribution 72a, so that overall there is a superimposed intensity distribution, as is again shown separately in FIG. 5 with 74.

Overall, an extensive, unsharp image 48 thus shines on the retina 46, and in fact significantly brighter than only the unsharp partial image of the central intensity distribution 72a. The eye lens 44 designs the real aerial image of the retina 46, on which the blurred image 48 illuminates.

6 shows a schematic block diagram for controlling the device according to the invention in a preferred embodiment.

A computer 80 is connected to a control 82 for the light sources 26 and 50. The computer 80 is also connected to an image acquisition device 29 to which the camera 22 is connected.

During a measurement, processes such as are shown in FIG. 7 occur in chronological order. Fig. 7 shows the situation with a conventional camera in the so-called "interlaced" method. Two fields are created in succession, which can be combined to form a full image. However, cameras that can only be operated in full-screen mode can of course also be used in the context of the present invention. In FIG. 7, lines a) and b) for the two fields are shown as pulses 90 and 92, the lines in which the camera is sensitive to the fields (integration time). In contrast, lines c) and d) represent lighting pulses 94 and control pulses 96.

The measurement is started with a control pulse 96, whereupon a first field 90 and a second field 92 are generated. 7 clearly shows that the two fields have a certain overlap area x, that is to say a time range in which both fields are sensitive to light.

In a first cycle I, the two fields are only recorded with the general lighting 34 switched on.

In the following cycle II, the light sources 26 and 50 are briefly switched on, as indicated by the lighting pulse 94, for example at the point in time at which both fields are sensitive to light.

The computer 80 now has two fields from cycle I only with general lighting 34 and from cycle II two fields with light sources 26 and 50 switched on. General lighting 34 can also be switched off in cycle II.

In this way, two full images are obtained, the first of which was taken only with the general lighting 34 and the second with the light sources 26 and 50. Alternatively, such a sequence can also be generated within two fields, in that the first field is recorded only with general lighting and the second field alone or additionally with the light source. In this respect, the invention is not subject to any restrictions.

The desired positions can now be determined manually or automatically from the images recorded in this way (cf. FIG. 3) in the manner already mentioned.

Claims

Patent claims

1. Device for adjusting a position of at least one lens of a pair of glasses (16) relative to the position (x _r , y _r , x _lf γ _x ) of a pupil (62r, 621) of an eye (14) of a person (12) assigned to the lens , with a lighting device (24) for an eye area (61) of the person (12) wearing a still unglazed glasses frame (18), with at least one camera (22) for generating an image (60) of the eye area (61), and with means for marking the position (x _r , y _r , x _lf y _x ) of the pupil (62r, 621) in the image (60), characterized in that the lighting device (24) contains at least one light source (26, 50), which works in a wavelength range whose light (42, 52) is reflected by the retina (46) of the eye (14) with a high degree of reflection, and that the camera (22) is sensitive to the wavelength of that emitted by the light source (26). Light (42) is optimized.

2. Device according to claim 1, characterized in that the light source (26) emits light (42) in the red to infrared range.

3. Device according to claim 1 or 2, characterized in that the light source (26) is a light-emitting diode.

4. Device according to claim 1 or 2, characterized in that the light source (26) is a gate of light-emitting diodes.

5. Device according to one or more of claims 1 to

4, characterized in that the lighting device (24) contains a lens (28).

6. Device according to one or more of claims 1 to

5, characterized in that the camera (22) has several color channels and that image signals of the color channel which comes spectrally closest to the light (42) emitted by the light source (26), in particular the red color channel, can be processed separately to form images.

7. Device according to one or more of claims 1 to

6, characterized in that at least two cameras (22) are provided, one of which is optimized in its sensitivity to the wavelength of the light (42) emitted by the light source (26).

8. Device according to one or more of claims 1 to

7, characterized in that the camera (22) and the light source (26) are aligned substantially along the same optical axis (23) to the eye (14).

9. Device according to claim 8, characterized in that the camera (22) and the light source are aligned inclined to one another by less than 2°, preferably less than 1°.

10. Device according to claim 8 or 9, characterized in that a beam splitter (30) for coupling the light (42) of the light source (26) is arranged in the beam path between the camera (22) and the eye (14), whereby the Light (42) is reflected away from the beam splitter (30) in the direction of the optical axis (23) of the camera (22).

11. The device according to claim 10, characterized in that the beam splitter (30) for the light (49) remitted by the eye (14) has a reflectance of less than 50%, preferably between 8% and 40%.

12. Device according to claim 11, characterized in that the degree of reflectance for wavelengths outside the wavelength range of the light (42) emitted by the lighting device (24) is reduced even further.

13. Device according to one or more of claims 10 to

12, characterized in that a light trap (32) is arranged on the side of the beam splitter (30) facing away from the light source (26).

14. Device according to one or more of claims 8 to

13, characterized in that additional light sources (50) directed at the eye area (61) are provided outside the optical axis (23).

15. Device according to claim 14, characterized in that the additional light sources (50a, 50b) are arranged uniformly around the optical axis (23) and are inclined to it.

16. Device according to one of the several of claims 1 to 15, characterized in that the beam path between Camera (22) and lighting device (24) on the one hand and the eye (14) on the other hand have a length (D) of several meters, preferably between 2 and 8 meters.

17. Device according to claim 16, characterized in that the beam path is folded.

18. Device according to one or more of claims 1 to 17, characterized in that, in addition to the lighting device (24, 50), general lighting (34) is provided for the eye area (61), and that means for controlling the camera (22) are provided, such that the camera (22) alternatively records a first image (60) only with the general lighting (34) with the light source (26) switched off and a second image (60) with the light source (26, 50) switched on.

19. Device according to claim 18, characterized in that the camera (22) records the second image (60) with the general lighting (34) switched off.

20. Device according to claim 18 or 19, characterized in that the camera (22) records the first and second images (60) in immediate succession.

21. Device according to claim 20, characterized in that the camera (22) is a line camera and that the camera

(22) records the first and second images (60) as fields of a full image.

2. Method for adjusting a position of at least one lens of a pair of glasses (16) relative to the position (x _r , y _r , x _x , γ _λ ) of a pupil (62r, 621) of an eye (14) of a person (12) assigned to the lens ), in which an eye area (61) of the person (12) wearing a still unglazed glasses frame (18) is illuminated by means of a first light source (26), an image (60) of the eye area (61) is generated, and the position (x _r , y _r , x _x , y _x ) of the pupil (62r, 621) is marked in the image (60), characterized in that the eye area (61) is illuminated with light (42, 52) from a wavelength range that is from Retina (46) of the eye (14) is reflected with a high degree of reflectance, and that the image (60) of the eye area (61) is generated with a sensitivity optimized to the wavelength of the light (42, 52).

23. The method according to claim 22, characterized in that light (42) is emitted in the red to infrared range.

24. The method according to claim 22 or 23, characterized in that the image (60) is recorded essentially along the same optical axis (23) along which the eye area (61) is illuminated.

25. The method according to claim 24, characterized in that the eye area (61) is additionally illuminated from at least one direction outside the optical axis (23).

26. The method according to claim 25, characterized in that the eye area (61) also comes from several directions is illuminated by means of second light sources (50a, 50b), the directions being arranged uniformly around the optical axis (23) and inclined to it.

27. The method according to one or more of claims 22 to 26, characterized in that the eye area (61) is illuminated in addition to the light sources (26, 50) by means of general lighting (34), and that alternatively a first image (60) only with the general lighting (34) with the light source (26, 50) switched off and a second image (60) with the light source (26, 50) switched on.

28. The method according to claim 27, characterized in that the second image (60) is recorded with the general lighting (34) switched off.

29. The method according to claim 27 or 28, characterized in that the first and second images (60) are recorded immediately one after the other.

30. The device according to claim 29, characterized in that the first and second images (60) are recorded as fields of a line full image.