Device for decoupling part of the radiation of an observation beam path of binoculars that is freely selectable at any time

Abstract

A device for outcoupling a portion of the radiation of an observation beam path of a binocular eyepiece for documentation or co-observation that is freely selectable at any time. For the outcoupling, a rotatable supporting unit, the axis of rotation of which is parallel to the axes of the observation beam paths, is arranged in the housing having the binocular eyepiece. Three optical elements are arranged on this supporting unit such that an outer and the middle optical element and, after rotation of the supporting unit, the middle and the other outer optical element are each located in one of the observation beam paths. Here, the two outer optical elements have a beam-splitting effect and outcouple a portion of the observation radiation into a common documentation beam path.

Claims

1. A device for outcoupling a portion of the radiation of an observation beam path of a binocular eyepiece that is freely selectable at any time, comprising: a rotatable supporting unit, an axis of rotation thereof being parallel to axes of observation beam paths of the eyepiece; wherein the rotatable supporting unit is arranged in a housing having the binocular eyepiece; wherein three optical elements are arranged offset on the supporting unit; wherein a first outer optical element and a middle optical element are each located in one of the observation beam paths; wherein after rotation of the supporting unit, the middle and a second outer optical element are each located in one of the observation beam paths; wherein the first outer optical element and second outer optical element have a beam-splitting effect and are arranged on the supporting unit such that, for the case that they are located in one of the observation beam paths, a portion of the observation radiation is outcoupled into a common documentation beam path; and whereby each of the first outer optical element, the second outer optical element and the middle optical element are offset from the axis of rotation and whereby selectable outcoupling of either of the observation beam paths for a right binocular eyepiece or a left binocular eyepiece to the common documentation beam path is enabled.

2. The device as claimed in claim 1, wherein the three optical elements are arranged offset, the rotatable supporting unit has a rotation range of +/−90° and has abutments or latching positions in end positions thereof.

3. The device as claimed in claim 1, further comprising an actuating element with or without gears arranged at the rotatable supporting unit.

4. The device as claimed in claim 1, further comprising an actuating element in the form of a switch, which is connected to a motorized drive arranged at the rotatable supporting unit.

5. The device as claimed in claim 1, wherein an operating mechanism of the rotatable supporting unit is structured bistably.

6. The device as claimed in claim 1, wherein the supporting unit comprises a plate.

7. The device as claimed in claim 1, wherein the first and second outer optical elements having a beam-splitting effect comprise beam-splitter cubes or plane-parallel plates.

8. The device as claimed in claim 1, wherein the optical elements having a beam-splitting effect outcouple a portion of the observation radiation into a common documentation beam path, wherein a proportion of the outcoupled radiation is up to 80%.

9. The device as claimed in claim 1, wherein the optical elements having a beam-splitting effect outcouple a portion of the observation radiation into a common documentation beam path, wherein a proportion of the outcoupled radiation is up to 50%.

10. The device as claimed in claim 1, wherein the common documentation beam path encloses an angle of 90° with the observation beam paths.

11. The device as claimed in claim 1, wherein the common documentation beam path further comprises a camera that records the image data.

12. The device as claimed in claim 1, wherein the middle optical element arranged between the two outer optical elements has no optical effect.

13. The device as claimed in claim 1, wherein the middle optical element arranged between the two outer optical elements has a beam-attenuating effect.

14. The device as claimed in claim 1, further comprising a display that incouples data, images or information opposite the common documentation beam path.

15. The device as claimed in claim 14, wherein the optical element having a beam-splitting effect, respectively located in the observation beam path, incouples the data, images or information.

16. The device as claimed in claim 1, further comprising spectrally-dependent filters arranged in the observation beam path and/or in the documentation beam path that are selectively insertable into the observation beam path or the documentation beam path.

17. The device as claimed in claim 16, wherein the spectrally-dependent filters are arranged on a filter wheel or other changer, which has a motorized drive.

18. The device as claimed in claim 1, further comprising fixed and/or variable stops arranged in the observation beam path and/or in the documentation beam path that are selectively insertable into the observation beam path and/or in the documentation beam path.

19. The device as claimed in claim 18, wherein the fixed and/or variable stops are arranged on a wheel or other changer, which has a motorized drive.

20. The device as claimed in claim 1, wherein the three optical components are structured as a monolithic block having correspondingly necessary optically effective surfaces.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The invention is described in more detail below on the basis of exemplary embodiments. In this respect:

(2) FIG. 1: is a schematic illustration of the solution for outcoupling from the left observation beam path of a binocular eyepiece,

(3) FIG. 2: is a schematic illustration of the solution for outcoupling from the right observation beam path of a binocular eyepiece,

(4) FIG. 3: is a schematic illustration of the solution for out- and incoupling from the/into the left observation beam path of a binocular eyepiece.

DETAILED DESCRIPTION

(5) The proposed device outcouples a portion of the radiation of an observation beam path of a binocular eyepiece that is freely selectable at any time.

(6) According to the invention, for this purpose a rotatable supporting unit, the axis of rotation of which is parallel to the axes of the observation beam paths, is arranged in the housing having the binocular eyepiece. Three optical elements are arranged offset on this supporting unit, embodied for example as a plate, wherein an outer and the middle optical element are each located in one of the observation beam paths and, after rotation of the supporting unit, the middle and the other outer optical element are each located in one of the observation beam paths. Here the two outer optical elements have a beam-splitting effect and are arranged on the supporting unit such that, for the case that they are located in one of the observation beam paths, a portion of the observation radiation is outcoupled into a common documentation beam path.

(7) With the invention it is possible to simply and quickly select one of the two observation beam paths for outcoupling a documentation beam path, by a beam-splitting optical element being swiveled into the selected observation beam path by means of rotating the plate, while an optical element without an optical effect is swiveled in the other observation beam path.

(8) The first example embodiment relates to the rotatable supporting unit, for example embodied as a plate, on which the three optical elements are arranged offset by 90°, at its outer edge. Here an outer and the middle optical element are located in one of the observation beam paths respectively and, after rotating the plate by 90°, the middle and the other outer optical element are located in one of the observation beam paths respectively.

(9) This thus results in a rotation range of +/−90° for the rotatable plate. In its end positions, the rotatable plate has abutments or latching positions. The two end positions should be haptically clearly recognizable to the operator here.

(10) For example, the switch mechanism can be embodied in an advantageous way such that, after an initial movement, the rotatable plate moves on its own into one of the two (stable) end positions, i.e. that the adjustment range is designed bistably.

(11) Since the plate is only occupied by three optical elements, the unoccupied surface of the preferably circle-shaped plate can be cut off, thereby allowing substantial reduction of the necessary structural space.

(12) The rather small rotation range of +/−90° makes manual rotation possible. For this purpose there is an actuating element in the form of a lever, which directly or indirectly engages the rotatable plate. Chains, cables or push rods are conceivable as an indirect connection between the lever and the rotatable plate. Here, it is recognizable by observation of the position of the lever, which observation beam path is currently being outcoupled from.

(13) According to an example variant there is an actuating element in the form of a switch, which is connected to a motorized drive arranged at the rotatable plate.

(14) Firstly, this has the advantage that the switch can be positioned at an ergonomically favorable point. Secondly, when the switching between the two outcoupling variants happens sufficiently quickly, this has the possibility to generate stereo recordings of the test object. For this purpose, image data outcoupled successively from both observation beam paths would be recorded and filed in data storage, wherein each of the images is marked as part of a pair of stereo images. In this variant, it should preferably also be recognizable, which observation beam path is currently being outcoupled from. In this case, this can happen by application of the position of the switch or a separate display.

(15) The second example embodiment relates to the elements having a beam-splitting effect, which are embodied as a beam-splitter cube and can consist of glass, plastic or another optically transparent material.

(16) In another embodiment variant, the elements having a beam-splitting effect are embodied as a plane-parallel plate.

(17) For example, the embodiment is as a beam-splitter cube, since in this case there is no beam misalignment. However, for very critical applications, the use of an optical element without an optical effect in the observation beam path not used for outcoupling is absolutely necessary.

(18) In cases in which a beam misalignment in the total optical system can be tolerated, the use of plane-parallel plates is possible.

(19) Independent of their embodiment variants, the proportion of the radiation outcoupled from an observation beam path into a common documentation beam path is up to 80%, preferably up to 50%.

(20) According to an example embodiment, the common documentation beam path encloses an angle of 90° with the observation beam paths.

(21) The common documentation beam path for example has a camera for recording image data, wherein the documentation beam path can still be bent away by means of one or more mirror elements for technical and/or ergonomic reasons and can include further optical elements.

(22) The third example embodiment relates to the middle optical component arranged between the two outer optical elements, which has no optical effect.

(23) This optical element without an optical effect exclusively compensates different optical path lengths between the two observation beam paths.

(24) For example, in a way corresponding to the elements having a beam-splitting effect this optical element is embodied as a cube or a plane-parallel plate.

(25) In the case of the embodiment as plane-parallel plates, the optical element without an optical effect would also be embodied as a plane-parallel plate or could potentially be omitted, under consideration of the thus associated reduction in quality.

(26) In one example variant, the middle optical component arranged between the two outer optical elements has a beam-attenuating effect.

(27) On account thereof, it is possible for the optical image impressions of both observation beam paths to match one another. Here the attenuation need not correspond exactly to the percentage proportion of the outcoupling, but can be smaller or also greater, since the visual impression of brightness has a relatively large tolerance.

(28) For this purpose, FIG. 1 shows a schematic illustration of the solution for outcoupling image data from the left observation beam path of a binocular eyepiece.

(29) In this case, the upper image of FIG. 1 shows a section illustration perpendicular to the optical observation axes.

(30) In the device according to the invention, arranged in the housing 1 having (not illustrated) a binocular eyepiece is a rotatable plate 4, the axis of rotation 5 of which is parallel to the axes of the two observation beam paths 2 and 3 of the binocular eyepiece. In this case, the possible rotational movement of the plate 4 is documented with the arrow 6. Three glass cubes 7, 8 and 9 are arranged offset on the plate 4, wherein the glass cubes 7 and 9 are located in one of the observation beam paths 2 and 3 respectively.

(31) The glass cube 7 located in the observation beam path 2 is embodied as a beam-splitter cube and outcouples a portion of the radiation of the observation beam path 2 into the common documentation beam path 10. The glass cube 9 located in the observation beam path 3 has no optical effect.

(32) The lower image of FIG. 1 shows a schematic illustration of the outcoupling, seen perpendicularly from above with respect to the plane spanned by the observation beam paths.

(33) A portion of the radiation 2′ of the observation beam path 2 is outcoupled as a documentation beam 10′ into a documentation beam path 10 by the beam-splitter cube 7 located in the observation beam path 2. The beam-splitter cube 7 is arranged on the plate 4 such that the radiation 10′ is outcoupled to the left into the documentation beam path 10 at an angle of 90°. The radiation 3′ of the observation beam path 3 is not affected by the glass cube 9 located in the observation beam path 3. The thickness of the arrows used for the illustration of the radiations 2′, 3′ and 10′ should simultaneously exemplarily document the energy flux.

(34) In contrast to FIG. 1, FIG. 2 shows a schematic illustration of the solution for outcoupling image data not from the observation beam path from the left, but from the observation beam path from the right of a binocular eyepiece.

(35) For this purpose, the plate 4 was rotated counter-clockwise by 90°. By this rotation: the beam-splitter cube 7 was swiveled out from the observation beam path 2, the glass cube 9 was swiveled out from the observation beam path 3 and into the observation beam path 2, and the beam-splitter cube 8 was swiveled into the observation beam path 3.

(36) The upper image of FIG. 2 in turn shows a section illustration along the optical observation axes.

(37) In the device according to the invention, arranged in the housing 1 having (not illustrated) a binocular eyepiece is a rotatable plate 4, the axis of rotation 5 of which is parallel to the axes of the two observation beam paths 2 and 3 of the binocular eyepiece. In this case, the possible rotational movement of the plate 4 is documented with the arrow 6. Three glass cubes 7, 8 and 9 are arranged offset on the plate 4, wherein the glass cubes 8 and 9 are located in one of the observation beam paths 2 and 3 respectively.

(38) While the glass cube 9 located in the observation beam path 2 has no optical effect, the glass cube 8 located in the observation beam path 3 is embodied as a beam-splitter cube and outcouples a portion of the radiation of the observation beam path 3 into the common documentation beam path 10.

(39) The lower image of FIG. 2 shows in turn a schematic illustration of the outcoupling, seen perpendicularly from above with respect to the plane spanned by the observation beam paths.

(40) A portion of the radiation 3′ of the observation beam path 3 is outcoupled as a documentation beam 10′ into the documentation beam path 10 by the beam-splitter cube 8 located in the observation beam path 3. The beam-splitter cube 8 is arranged on the plate 4 such that the radiation 10′ is outcoupled to the left into the documentation beam path 10 likewise at an angle of 90°. The radiation 2′ of the observation beam path 2 is not affected by the glass cube 9 located in the observation beam path 2. The thickness of the arrows used for the illustration of the radiations 2′, 3′ and 10′ should simultaneously exemplarily document the energy flux here also.

(41) Since the light path is in general reversible, all described outcoupling variants can also be used to incouple information into an optical system.

(42) When exclusively using the device, the beam-splitters must then be rotated by 180° such that the light energy is deflected toward the observer.

(43) According to a fourth example embodiment, there is in addition a display for incoupling data, images or information, which is arranged opposite the common documentation beam path. In- and outcoupling take place independently of one another here, but can also be combined.

(44) In this variant, it is particularly advantageous that the optical element having a beam-splitting effect, which is located in the observation beam path respectively and realizes the outcoupling of the documentation radiation, is used for incoupling the data, images or information.

(45) Any desired information can be fed into one of the observation beam paths by use of this display.

(46) Since only a portion of the light energy is deflected in the direction of the observer by the beam-splitter and the remaining portion passes through the beam-splitting element in the imaging direction, it is sensible that feeding information in is briefly switched off while recording image data in the documentation beam path, wherein the switching off can be synchronized with the image recording. On account thereof, possible superpositions of the image to be documented with the information fed in are prevented.

(47) Furthermore it can be shown by use of the display, for example, which of the observation beam paths is currently being outcoupled from and also fed into. This is sensible whenever the switching between the observation beam paths is motorized and there is a lever, the position of which shows this information.

(48) In this respect, FIG. 3 shows a schematic illustration of the inventive solution for outcoupling and feeding-in from the/into the left observation beam path of a binocular eyepiece.

(49) The schematic illustration of the outcoupling and feeding-in corresponds to the lower images of FIGS. 1 and 2, in which the line of vision is oriented perpendicularly from above onto the plane spanned by the observation beam paths.

(50) A portion of the radiation 2′ of the observation beam path 2 is outcoupled as a documentation beam 10′ into a documentation beam path 10 by the beam-splitter cube 7 located in the observation beam path 2. The beam-splitter cube 7 is arranged on the plate 4 such that the radiation 10′ is outcoupled to the left into the documentation beam path 10 at an angle of 90°. The radiation 3′ of the observation beam path 3 is not affected by the glass cube 9 located in the observation beam path 3.

(51) The information generated by the display 11 is fed as radiation 11′ into the observation beam path 2 by the beam-splitter cube 7. In this case, the splitter layer of the beam-splitter cube 7 undertakes both the outcoupling of the radiation 2′ from the, and the feeding of the radiation 11′ into the, observation beam path 2.

(52) The radiation 11′ generated by the display 11 is also not affected by the glass cube 9 located in the observation beam path 3.

(53) The thickness of the arrows used for the illustration of the radiations 2′, 3′, 10′ and 11′ should simultaneously exemplarily document the energy flux here also. The radiation 11′ fed into the observation beam path 2 is illustrated as a dashed line.

(54) The schematic illustration of the inventive solution shown in FIG. 3 also applies analogously for the outcoupling and feeding-in from the/into the right observation beam path of a binocular eyepiece. Since the outcoupling and the feeding-in occur from the and into the observation beam path 3, these functions are undertaken by the splitter layer of the beam-splitter cube 8.

(55) According to a further example embodiment, the inventive device for outcoupling image data from a selectable observation beam path of a binocular eyepiece can be supplemented by spectrally-dependent filters, which are arranged in the observation and/or in the documentation beam path and are selectively insertable into the beam path. The spectrally-dependent filters are preferably arranged for this purpose on a filter wheel or similar, which has a motorized drive.

(56) With the aid of the spectrally-dependent filters, wavelength-specific observation situations can be generated and associated image recordings documented. In this case it is even possible to generate a different spectral characteristic in the observation beam path than in the documentation beam path. It is also possible to realize pseudo-multispectral, i.e. sequential, recordings by use of a motorized adjustment of the spectrally-dependent filters.

(57) Furthermore, the inventive device can be supplemented by use of fixed and/or variable stops, which are likewise arranged in the observation and/or documentation beam path and are selectively insertable into the beam path. The fixed and/or variable stops are preferably also arranged on a wheel or similar, which has a motorized drive.

(58) In this case, both a fixed, step-wise adjustable diameter or a continuously adjustable iris stop are provided as stops, by use of which the depth of field of the observation situations and associated recordings can be varied.

(59) When the stops are only arranged in the documentation beam path, the depth of field can only be varied for the documentation beam path. But in this case the identity between the visual observation and the documented image is eliminated. These stops can also be used for controlling the exposure of the image recording. For this purpose, they should be easy to operate.

(60) According to a last example embodiment, the three optical components can be embodied as a monolithic block having the correspondingly necessary optically effective surfaces. The rotatable plate can be dispensed with here, if the monolithic block is rotated as a whole.

(61) This variant has the advantage that boundary surface losses can be avoided and the alignment complexity substantially reduced.

(62) With the solution according to example embodiments of the invention, a device, with which a portion of the radiation of an observation beam path of a binocular eyepiece that is freely selectable at any time can be outcoupled is provided. The beam path, to be used for a photographic documentation, of an optical appliance having a binocular eyepiece can be freely selected and changed here, without structural changes being necessary for this.

(63) The selection is extremely simple to realize with the present solution and also possible while observing through the binocular eyepiece, for the purpose of which the operator does not need to turn his view away from the binocular eyepiece.

(64) Although the proposed solution is for example provided for outcoupling image data from an ophthalmological appliance, it can however be used for all optical systems, which have a binocular eyepiece, for which beam-splitting of one of the observation beam paths is necessary and the observation beam path to be used for the outcoupling must be variable.

(65) The arrangement according to the invention of only three optical elements and the thus associated multiple use of the optical element without an optical effect make a very compact device possible.

(66) Compared to similar adjustment devices known from the prior art, the present solution requires a substantially smaller structural space. This is of advantage in particular for such appliances, in which the user must also be able to look at his object past the appliance, which for example is the case for a slit-lamp.

(67) It is furthermore particularly advantageous that a very simple and quick change of the observation beam path used for outcoupling is possible by use of the rotating adjustment.