DE19504427B4 - stereomicroscope - Google Patents

Abstract

Stereo microscope, with
At least three observation and / or documentation pupils (10, 11, 12) defining stereoscopic primary and secondary observation beam paths (I, II), and
- A the main objective (2) downstream, rotatable beam splitter element (4), the at least two beam splitter surfaces (4.1, 4.2), which a defined proportion of the object to be observed from the (1) coming light to the primary and secondary observation beam paths (I , II) transmit or reflect,
characterized in that
- The beam splitter element (4) about an axis (13) is rotatable, which coincides with one of the optical axes of the stereoscopic partial beam paths of the primary and secondary observation beam paths (I, II).

Description

The The present invention relates to a stereomicroscope with at least three observation and / or documentation beam paths including a suitable Beam splitter element, the variable orientation of the observation and / or documentation beam paths in a defined angle range allows.

at the use of stereomicroscopes in microsurgery will next to a viewing opportunity for one Main observers often also another observation option for a second Surgeons or assistants needed. There are a number of Solutions.

Thus, from DE-AS 12 17 099 and the DE 36 02 095 A1 It is known to vary the orientation of the primary observation beam path of the main observer relative to the secondary observation beam path of a co-observer.

The used in these devices, rotatable beam splitter elements, with which a division of the light coming from the object in the direction Main and Co-Watcher Observation Beam takes place, but have certain disadvantages. So they build there proposed beam splitter elements relatively bulky. This has the consequence that relatively long glass paths for the passing partial beam paths result. With the length the glass paths increased However, also the required effort for optical corrective measures in the respective beam splitter element. In addition, a larger number undesirable Reflections in this component the consequence. Furthermore arises at a voluminous such beam splitter element also correspondingly bulky construction of the entire Surgical microscope, i. an unwanted enlargement of the Working distance between the binocular tube and the field of view. The Consequence are unfavorable Ergonomic working conditions for the operating surgeon.

When used beam splitter element from the DE 36 02 095 A1 also results in varying the observation directions of main and co-observer, the undesirable consequence that when overlapping the partial beam paths of main and co-observer, a reduction of the perceived object brightness for the main observer takes place. The optical observation quality thus varies with respect to the perceived object brightness for the main observer and impairs its perception of the observed field of view in an undesired manner.

The DE 29 49 428 A1 discloses a surgical microscope that allows for a main observer and a co-observer to observe an object area with stereoscopic beam path. The stereoscopic observation beam path of main and co-observer coincides in a common observation pupil. In this coincident observation beam path, a beam splitter is provided, which decouples a portion of the light coming from the object area to the co-observer and releases a corresponding portion to the main observer.

Furthermore There are also solutions where such a variable adjustment of the angle between Main and co-watcher is not provided, but rather a fixed or constant orientation of primary and secondary observation beam paths in 180 ° or 90 ° orientation to each other. In particular, such, firmly oriented to each other Observational directions of main and Co-observers will meet the requirements in modern microsurgery, however no longer fair. required rather becomes a variable possibility for the optional orientation of the observation directions of main and fellow watchers.

The the same problem arises, moreover, when a conventional Stereomicroscope no usual Binocular tubes for direct viewing of an object, but is designed as a video stereo microscope. In this case are on Place the usual Binocular Tubes Electro-optical image sensors such. CCD arrays in the corresponding Documentation beam paths in the Stereomicroscope provided. The same applies to a mixed interpretation, i.e. a surgical microscope with a possibility for immediate viewing including documentation beam paths with such electro-optical Imagers.

task the present invention is to provide a stereomicroscope that a variable orientation of the observation directions of a main and at least one co-observer in a defined angular range allows and the mentioned Disadvantages of the prior art avoids. The used for this Beam splitter element in the stereomicroscope should have a sufficient light economy for main and co-watchers. Furthermore, the stereomicroscope should be both in conventional Way of enabling immediate consideration via binocular tubes as well as a video stereo microscope can be interpreted.

These Task is solved by a stereomicroscope having the features of claim 1.

advantageous Find embodiments of the stereomicroscope of the invention in the subclaims.

According to the invention is in Stereomicroscope now a beam splitter element used, the the same proportion of the light coming from the object to be observed towards the primary as well as the secondary observation beam path transmitted and reflected. Here is both the transmission as well as the reflection in the beam splitter element or the corresponding surfaces of the beam splitter element spectrally and in terms of intensity for all beam paths identical to choose, i. all acting as beam splitter surfaces Surfaces are as identical as possible with regard to these properties.

Further the beam splitter element is rotatable about an axis which coincides with a the optical axes of the stereoscopic partial beam paths of Primary and Secondary observation beam paths coincide.

in the Comparison with the known prior art now results due to the dimensioning according to the invention the beam splitter element both a smaller volume and construction an improved observation or imaging quality for the stereomicroscope.

The smaller construction volume of the beam splitter element in turn has due the shorter one Glass paths a much lower optical correction effort result. Furthermore, there are no problems with multiple reflections, such as possibly occurring double images or the like .. Furthermore, the entire Stereomicroscope according to the invention thus designed to be smaller, which in turn is favorable for work ergonomics when used as a surgical microscope.

Finally kick in the stereomicroscope according to the invention when varying the observation directions and thus the turning of the Beam splitter element no fluctuations in the perceived Object brightness more, it also results in intermediate positions partially overlaid Observing beam paths one Consistently perceived object brightness in all observation beam paths or Documentation beam paths.

Further allows the stereomicroscope according to the invention now a variable relative orientation of a main and a Co-observer beam path in a defined angle range to each other.

The According to the invention stereomicroscope furthermore as usual Stereomicroscope with binocular tubes for direct observation of the visual field to be used by the observers. alternative however, it can also be designed as a pure video stereomicroscope, in the electro-optical in the documentation beam paths suitable Image sensor can be arranged.

Further Advantages and details of the stereomicroscope according to the invention result from the following description of exemplary embodiments with reference to FIG enclosed drawings.

there shows

1 an embodiment of the stereomicroscope according to the invention in a schematic representation;

2 a perspective view of the beam splitter element used from the embodiment according to 1 ;

3a - 3c in each case the plan view of the beam splitter element 2 in different angular positions including the respectively used observation and / or documentation pupils in the primary and secondary observation beam path.

In 1 a schematic representation of a first embodiment of the stereomicroscope according to the invention.

The object being viewed ( 1 ) coming light via a shared by both stereoscopic observation beam paths main objective ( 2 ) to a magnification change device ( 3 ), which in the representation of the 1 only schematically indicated. As a magnification change device, for example, a known Pankrat system can be used.

in the illustrated embodiment is one of all observation beam paths shared, only one Magnification change device provided, which then also a corresponding optical diameter requires to all Observation beam paths to include.

Alternatively to the illustrated arrangement 1 It is also possible, the respective magnification change device ( 3 ) after the beam splitter element ( 4 ) in the observation beam paths of main and co-observer. For this purpose, then known stereo pan rates with two partial beam paths in each of the Beo observation beam paths are used.

In the parallel beam path behind the magnification change device ( 3 ) follows in the illustrated embodiment of 1 the beam splitter element ( 4 ), of which in this illustration two partially reflecting and partially transmitting surfaces ( 4.1 . 4.2 ) are visible. These surfaces ( 4.1 . 4.2 ) are designed in the illustrated embodiment partially permeable or partially reflecting that half of the light reaching it in the direction of primary observation beam path (I) is transmitted, while the other half in the direction of the secondary observation beam path (II) is reflected. Thus, identical observation conditions in the primary and secondary beam path are realized. As far as possible, both surfaces shall be interpreted identically with regard to their reflection and transmission characteristics.

For concrete call construction and the mode of operation of the beam splitter element used ( 4 ) as well as possible alternative embodiments, should be made to the following description of 2 and 3 pointed.

Is recognizable in the representation of 1 Furthermore, at the beam splitter element ( 4 ) arranged absorbent element ( 4.3 ), which suppresses unwanted multiple reflections in the optical system of the stereomicroscope according to the invention, in particular in the beam splitter element (US Pat. 4 ). As a suitable absorbent element ( 4.3 ), a high-absorption neutral-glass filter, for example, which absorbs light in the visible wavelength range and, for example, at the beam splitter element (FIG. 4 ) is angekittet. Such filters are available, for example, from Schott.

When choosing a suitable absorbing element, it is further to be ensured that the refractive indices of the adjoining materials of the beam splitter element ( 4 ) and the absorbing element are as identical as possible in order to suppress any resulting reflections that would otherwise occur at the boundary layer.

In the two stereoscopic partial beam paths of the primary observation beam path (I), downstream optical elements ( 5a . 5b ), which is an intermediate image of the object under consideration ( 1 ) in a plane where, in the illustrated embodiment, electro-optical image sensors ( 6a . 6b ) are arranged. As suitable electro-optical image sensor ( 6a . 6b ) come about known CCD arrays in question.

This in 1 illustrated embodiment of the stereomicroscope according to the invention is therefore designed as a video stereomicroscope. Alternatively, however, it is also possible for the beam splitter element ( 4 ) the known observation optics of a binocular tube with eyepiece and Tubuslinsen in the primary and secondary observation beam paths (I, II) after the observers direct observation of the object ( 1 ) enable. Such Binokulartubus is for example from the DE 26 54 778 A1 the applicant known.

Further is also a combination of such a realizable that about in Primary observation beam path a known observation optics for immediate consideration of the Object is provided while in the secondary observation beam path Electro-optical image sensor can be arranged and vice versa.

In the left stereoscopic partial beam path of the secondary observation beam path (II), which is visible in this illustration, is also an optical element ( 7a ), via which the reflected portion of the object ( 1 ) incoming light in the direction of an electro-optical image sensor ( 9a ) is deflected. Furthermore, a deflection element ( 8th ) in the form of a deflection mirror in this stereoscopic partial beam path of the secondary observation beam path (II). Possibly. can be used as a deflecting element ( 8th ) also find a prism use.

in the illustrated embodiment of the stereomicroscope according to the invention Now the orientation of the primary observation beam path (I) is fixed, while the orientation of the secondary observation beam path in an angular range between 90 ° and 180 ° relative to the orientation of the Primary observation beam path (I) can be varied. Thus, a total rotation is 90 ° for the secondary observation beam path relative to the primary observation beam path (I) possible.

For this purpose, the beam splitter element ( 4 ) is arranged rotatably about a rotation axis in the stereomicroscope. This axis of rotation is defined by a shared observation pupil of the primary and the secondary beam path in the beam splitter element or its optical axis.

The in the secondary observation beam path (II) arranged optical elements ( 7a . 8th . 9 ) are connected to the rotatable beam splitter element ( 4 ) and thus rotatable relative to the main objective ( 2 ) and the magnification change device ( 3 ) arranged. The optical elements ( 5a . 5b ; 6a . 6b ) in the primary observation beam path (I), however, are stationary relative to the main objective ( 2 ) and the magnification change sel-facility ( 3 ) oriented.

Alternatively to the fixed arrangement of the primary observation beam path (I) and the thereto variable arrangement of the secondary observation beam path (II) as in the illustrated embodiment of 1 it is always possible, for example, to arrange the secondary observation beam path (II) fixedly to the housing of the stereomicroscope, while, relative thereto, the primary observation beam path is arranged pivotably in a defined angular interval. In such an alternative arrangement as well, a magnification change device shared by all the stereoscopic partial beam paths is arranged as in FIG 1 , used.

Based on 2 Next, the beam splitter element used in this embodiment ( 4 ) and how it works.

This in 2 Perspective illustrated beam splitter element ( 4 ) consists of three separate prisms ( 4a . 4b . 4c ), whereby between two prisms ( 4a . 4b ) of cube-shaped cross-section which abut one another, a third prism ( 4c ) is positively inserted, preferably aufgekittet is. The surfaces ( 4.1 . 4.2 ) on which the three prisms ( 4a . 4b . 4c ), serve as splitter surfaces ( 4.1 . 4.2 ), at which the incident light is transmitted or reflected respectively in the ratio 50:50. It is essential here that both splitter surfaces ( 4.1 . 4.2 ) are as identical as possible from the transmission and reflection properties.

Alternatively, with desired different intensity ratios in the primary and secondary observation beam path, it is also possible to choose other intensity distribution ratios, such as 70:30, etc. It is only important again for both splitter surfaces ( 4.1 . 4.2 ), to choose a largely identical division ratio between reflected and transmitted intensity.

It is now possible, to provide a number of different beam splitter elements, the different division ratios and used as needed in the stereomicroscope according to the invention become. For example,

could be realized be, in the primary observation beam path to provide a greater transmitted intensity as in the secondary observation beam path etc.

Also clearly visible in the perspective view of 2 that at the beam splitter element ( 4 ) arranged absorbent element ( 4.3 ), which serves to suppress unwanted reflections already described above. The absorbent element ( 4.3 ) is on the surface of that prism ( 4a ), where no deflection of the light is provided in the direction of the secondary observation beam path. In the direction of the secondary observation beam path, only the portion which is incident on the other splitter surface ( 4.2 ).

In addition, it is possible to use the beam splitter element ( 4 ) on its underside by means of a - in 2 not shown - seal cover glass, to prevent that about the edge is exposed to external influences over time. For this purpose it is also possible to use the splitter surfaces ( 4.1 . 4.2 ) so that they do not reach all the way to the upper edge of the beam splitter element ( 4 ), but rather already in the interior of the beam splitter element ( 4 ) and are thus largely insulated against external influences such as humidity etc.

The mode of operation of the beam splitter element ( 4 ) is explained below using the 3a - 3c explained.

The beam splitter element ( 4 ) has three observation and / or documentation pupils ( 10 . 11 . 12 ) for the partial scanning beam paths of the primary and secondary observation beam path, one of these pupils ( 13 ) is always used both by the primary and at the same time by the secondary observation beam path.

The beam splitter element ( 4 ) is, as already mentioned above, rotatable about the optical axis ( 13 ) of the shared pupil ( 13 ) arranged in a stereomicroscope.

In the 3a - 3c the fixed orientation direction of the main or primary observer is marked by the hatched pupils. This is aligned in the illustrated embodiment, that the connecting line of the two pupils ( 10 . 11 ) runs in the direction of the transverse axis of the sheet.

The two fellow observer pupils ( 11 . 12 ) can now be rotated by 90 ° to this fixed orientation. A corresponding rotation of the beam splitter element ( 4 ) around the axis ( 13 ) by 45 ° including the resulting orientations of the primary and secondary observation beam paths or -pupils is in the 3b and 3c shown. Clearly recognizable here is how the orientation of the observation direction of the co-observer can be changed by a total of 90 °, while the observation direction of the main observer ters remains unchanged.

In order during this rotation of the beam splitter element ( 4 ) to ensure a sufficient optical quality in the two observation beam paths, the beam splitter element used ( 4 ) meet certain optical requirements.

For example, the effective beam splitter surfaces ( 4.1 . 4.2 ) are designed in terms of their reflection and transmission properties so that both spectrally and in terms of intensity sufficiently identical conditions in reflection and transmission for both beam splitter surfaces ( 4.1 . 4.2 ) are present.

Furthermore, it must be ensured that the edge ( 15 ) at the point where the three half-cube prisms ( 4a . 4b . 4c ) coincide when rotating the beam splitter element ( 4 ) is not visible in the pupils of the main and co-observer. This edge ( 15 ) through in non-illustrated intermediate positions of the beam splitter element ( 4 ) a pupil ( 10 ) of the main observer and may not lead to any impairment in the actual image. This is ensured in the stereomicroscope according to the invention in that the beam splitter element ( 4 ) is arranged in the parallel beam path, wherein the edge is not in the immediate vicinity of an intermediate image plane. Otherwise, an image of the edge could take place through the optical system of the stereomicroscope and the edge could interfere with the migration of the pupil of the main observer.

Becomes the stereomicroscope according to the invention as a pure video stereo microscope Furthermore, appropriate displays or monitors are to be provided, on which a stereoscopic view of the captured images is possible from each considered object. This can be about in known way about the sequential representation of stereoscopic partial images and according thereto synchronized shutter glasses take place.

Claims (13)

Stereomicroscope, with - at least three observation and / or documentation pupils ( 10 . 11 . 12 ), which define stereoscopic primary and secondary observation beam paths (I, II), and - a main objective ( 2 ) downstream, rotatable beam splitter element ( 4 ), the at least two beam splitter surfaces ( 4.1 . 4.2 ), which has a defined proportion of the object to be observed ( 1 ) transmitted light to the primary and secondary observation beam paths (I, II) out or reflected, characterized in that - the beam splitter element ( 4 ) about an axis ( 13 ), which coincides with one of the optical axes of the stereoscopic partial beam paths of the primary and secondary observation beam paths (I, II). Stereo microscope according to claim 1, wherein three observation and / or 10 . 11 . 12 ) and the observation and / or documentation pupil ( 11 ) around which the beam splitter element ( 4 ) is rotatable in each rotational position of a stereoscopic beam path of the primary and secondary observation beam path (I, II) is usable. Stereomicroscope according to claim 2, wherein the beam splitter element ( 4 ) of two prisms with a semi-cube-shaped cross section ( 4a . 4b ), which with one edge ( 15 ), and a third prism ( 4c ) is positively arranged between the other two and the boundary surfaces between the prisms ( 4a . 4b . 4c ) as beam splitter surfaces ( 4.1 . 4.2 ) and the beam splitter element ( 4 ) is further arranged in the stereomicroscope in the parallel beam path. Stereomicroscope according to claim 3, wherein all beam splitter surfaces ( 4.1 . 4.2 ) of the beam splitter element ( 4 ) have spectrally and intensity identical reflection and transmission properties. Stereomicroscope according to claim 4, wherein all beam splitter surfaces ( 4.1 . 4.2 ) cause a split between reflected and transmitted beams in the ratio 50:50. Stereomicroscope according to claim 3, wherein the beam splitter element ( 4 ) is rotatable by 90 °. Stereomicroscope according to claim 3, wherein the beam splitter element ( 4 ) a light-absorbing element ( 4.3 ) on the secondary observation beam path (II) facing away from. Stereomicroscope according to claim 7, wherein the light-absorbing element ( 4.3 ) is designed as a neutral glass filter, which has an identical refractive index as the adjacent prism ( 4a ) having. Stereomicroscope according to at least one of the preceding claims, wherein in the primary and secondary observation beam paths (I, II) electro-optical image sensor ( 6a . 6b . 9a ) are arranged. Stereomicroscope according to at least one of the preceding claims, wherein the beam splitter element ( 4 ) Imaging optics ( 5a . 5b . 7a ) for generating an intermediate image in the stereoscopic Primary and secondary observation beam paths (I, II) are ordered by and the imaging optics ( 7a ) in the secondary observation beam path (II) fixed to the rotatable beam splitter element ( 4 ) connected is. Stereomicroscope according to at least one of the preceding claims, wherein a magnification change device common to all stereoscopic observation beam paths (I, II) ( 3 ) between the beam splitter element ( 4 ) and a main objective common to all stereoscopic observation beam paths ( 2 ) is arranged. Stereomicroscope according to at least one of the preceding Claims, wherein Raff change switching facilities the Arranged downstream beam splitter element in the primary and secondary observation beam paths are. Stereomicroscope according to one of the preceding claims used as a surgical microscope.