DE4301574B4 - Device for observing the fundus, in particular an ophthalmoscope - Google Patents

Abstract

Device for observing the fundus, in particular an ophthalmoscope, with an illumination and an observation beam path, wherein
The illumination beam path in the direction of illumination comprises a light source, a collimator, a light field diaphragm, an optical imaging system arranged behind the light field diaphragm and a deflecting mirror,
- The deflecting mirror (10) has an opening (9) for the observation beam path in the region of the optical axis (12),
The optical axis (4) of the illuminating beam path in the illuminating direction behind the deflecting mirror (10) coincides with the optical axis (12) of the observation beam path,
- The optical imaging system (8, 40) generates an image (14) of the light-emitting region of the light source behind the deflecting mirror (10), and
- A beam expansion device (28) is arranged in the illumination beam path between the imaging system (8, 40) and the deflecting mirror (10), which generates a parallel offset in the illumination beam path that is central to the optical axis (4) and thereby the distance of light beams originally close to the axis to the optical axis ( 4) enlarged.

Description

The invention relates to a device for observation of the fundus, especially an ophthalmoscope, with an illumination and an observation beam path, where the illumination beam path in the direction of illumination is a light source, a collimator, a light field diaphragm, one behind the light field diaphragm arranged optical imaging system and a deflecting mirror.

Such devices or ophthalmoscopes serve to observe the living fundus for medical diagnostic Purposes. The dioptric system of the Eye of the patient, which images the fundus to infinity, if the patient is accommodated to infinity. With the so-called The doctor can see direct ophthalmoscopy from a short distance (some cm) directly into the patient 's eye using the ophthalmoscope and sees the fundus upright in the infinity with an enlargement about 15 if his eye is also accommodated at infinity.

• – Es muß eine ausreichende Helligkeit bei gleichmäßiger Ausleuchtung des Augenhintergrundes erzielt werden.
• – Der ausgeleuchtete Bereich soll scharf begrenzt sein.
• – Der ausgeleuchtete Bereich soll sich mit dem durch die Augenpupille des Patienten begrenzten Gesichtsfeld des Arztes decken.
• – Es sollen keine störenden Reflexe des Beleuchtungslichts an der Hornhaut des Patienten und kein störendes Streulicht in das Auge des Arztes gelangen.
• – Keine Teile der Beleuchtungsoptik sollen im Beobachtungsstrahlengang liegen und die Beobachtung stören.
• – Zum Ausgleich von Fehlsichtigkeit von Patient oder Arzt sollen verschiedene Linsen unterschiedlicher Brechkraft (positiv und negativ) in den Beobachtungsstrahlengang eingebracht werden können.

To observe the fundus of the eye, it must be illuminated from the outside through the pupil. The ophthalmoscope must therefore also perform lighting tasks. Accordingly, there are a number of requirements for the ophthalmoscope:

• - Adequate brightness must be achieved with uniform illumination of the fundus.
• - The illuminated area should be sharply delimited.
• - The illuminated area should coincide with the doctor's field of vision, which is limited by the patient's eye pupil.
• - No disturbing reflections of the illuminating light on the patient's cornea and no disturbing stray light should get into the doctor's eye.
• - No parts of the illumination optics should lie in the observation beam path and interfere with the observation.
• - To compensate for ametropia of the patient or doctor, different lenses of different refractive powers (positive and negative) should be able to be inserted into the observation beam path.

The construction of a conventional ophthalmoscope is in 6 shown. A light field diaphragm 6 is illuminated by a halogen incandescent lamp using collimation optics. The light field diaphragm 6 is used by an optical imaging system 8th mapped to infinity. The imaging beam is over a 90 ° deflection mirror 10 directed into the patient's pupil. The light source 2 , in particular their light-emitting area, shown on the deflecting mirror or just behind it (cf. 14 ). The aperture is created on the back of the eye (retina) 18 of the patient (cf. 6 (B) , The doctor 26 observed above the deflecting mirror 10 the fundus 18 of the patient.

This is made possible by the fact that the optical axes of the illumination and observation beam paths are tilted towards one another. This can reduce the effect of corneal reflexes. Another consequence of the tilting is that the illuminated and the observed area 26 . 22 do not collapse on the fundus. Only the overlapping area 24 can be used for observation, whereby light and observation surface are lost. The bundle cross section should also not be larger than the pupil at the location of the patient's eye in order to use all light and not to cut the illuminated field, which leads to vignetting at the edges if the pupil is not dilated.

Through the use of pupil dilating means, the illuminated and the observed area of the retina 22 . 26 and thus also their overlap 24 be enlarged, which makes handling the ophthalmoscope very easy. However, this is very uncomfortable for the patient concerned (severe, painful glare, inability to drive after treatment).

Without pupil dilating agents the pupil diameter goes to its minimum value through the glare of 1-2 mm back. This is particularly important in emergency situations in which pupil dilation Do not always use funds, but on the other hand A quick diagnosis would actually be essential, recognizing and diagnostic Evaluate the fund for the doctor very difficult and time consuming.

In order to make optimum use of the light emitted by the incandescent lamp in conventional ophthalmoscopes, the imaging optics are usually designed in such a way that they simultaneously image the incandescent filament of the lamp, which is imaged by the collimator into infinity, on the deflecting mirror or in its immediate surroundings. The focal point on the image side 14 the imaging optics is located in the mirror plane or just behind it. In this way, a narrow beam cross section is obtained at the location of the mirror, which cross section must lie completely on the mirror surface. The latter can thus be minimized and therefore no longer interferes in the observation beam path. After the deflection by the mirror, the lighting bundle continues divergent.

In order to be able to reduce the angle between the optical axes of the illumination and observation beam paths, DE-U-87 04 606.7 proposed to use a condenser for the lighting optics contains cylindrical lens surfaces. As a result, the spiral image can be pulled apart in the direction of the top edge of the mirror and compressed perpendicularly thereto, so that it can be placed closer to the top edge of the mirror overall.

In the DE-A-33 28 483 the upper edge of the deflecting mirror receives an arcuate recess within which the optical axis of the observation beam path lies. Around this recess there is a picture of a matching arc-shaped filament lamp.

However, both measures are not effective against the corneal reflexes mentioned. However, as in the DE-A-37 14 889 described by using polarized light for lighting effectively. The corneal reflex maintains the specified direction of polarization, so it can be weakened by a suitable angle-oriented analyzer. The light scattered back from the retina, however, is depolarized. Part of it can pass through the analyzer. The disadvantage of this ophthalmoscope is the very large overall light losses in the polarizers.

In the US 2,014,888 A. a two-part deflecting mirror is proposed for an ophthalmoscope, the parts of which lie in different planes. It enables the light coming from the illumination system to be detected and redirected both below and above the observation axis and thus to illuminate two areas of the retina symmetrically to the observation axis. However, it is then not possible to place the image of the light source on the deflecting mirror or in its immediate vicinity for good light utilization. Since the two parts of the deflecting mirror are illuminated by a divergent bundle, the cross section of the two deflected partial bundles in the pupil plane of the eye is inevitably significantly larger than the diameter of even a dilated pupil, so that the majority of the illuminating light does not fall into the eye, but on the iris and cornea produce strong scattered light or disturbing reflections.

The US 1,692,241 provides a perforated mirror for beam deflection for an ophthalmoscope. The observer looks through the hole, so that the illumination beam path is concentric with the observation beam path. On the one hand, it is also not possible with this concept to place the image of the light source on the deflecting mirror or in its immediate vicinity for good light utilization, so that here too the deflecting mirror must be illuminated by a divergent bundle and, in turn, problems with scattered light and reflections arise , On the other hand, the central area of the bundle of lights is hidden by the hole in the mirror. This leads to further light losses, in particular because the luminous intensity of the illumination is the highest around the illumination axis and the imaging errors of the illumination optics are lowest. In addition, when the pupil is small, the illuminated area on the retina assumes an annular shape due to the vignetting at the hole of the deflecting mirror, the central area of the visual field being illuminated only slightly or only inhomogeneously.

The invention has for its object a Device for observing the fundus, in particular to create an ophthalmoscope, which makes it possible even with severely constricted pupils a big Illuminated area of the fundus without disturbing corneal reflexes for observation to disposal to be able to diagnose quickly and safely. This task is according to the invention at a Device with the features of claim 1 solved. advantageous Developments of the device according to the invention are the subject of subclaims.

A device according to the invention for observation of the fundus, especially an ophthalmoscope, comprises thus one illumination and one observation beam path, where the illuminating beam path in the direction of observation is a light source, a collimator, a light field diaphragm, one behind the light field diaphragm arranged optical imaging system and a deflecting mirror includes. The deflection mirror has an opening for the observation beam path in the region of the optical axis on, and the optical axis of the illuminating beam path falls in the illuminating direction behind the deflecting mirror with the optical axis of the observation beam path together. So no through the central opening in the deflecting mirror Light is lost is advantageous in the illumination beam path a beam expansion device between the imaging system and the deflecting mirror arranged, a parallel to the optical axis parallel Offset created in the illumination beam path and thereby the distance originally Light rays close to the axis enlarged to the optical axis. The optical imaging system produces an image of the light emitting area the light source at a distance behind the deflecting mirror in which the pupil of the patient's eye is located.

In the device according to the invention for observing the fundus of the eye, the light-emitting region of the light source is thus imaged on the patient's cornea. The image scale of this illustration is chosen so that the helix image is smaller than the smallest eye pupil, so that no light can be lost at the eye pupil. In this way, the pupil diameter of the patient's eye has no influence on the size of the illuminated area on the fundus. This is only determined by the diameter of the light field diaphragm, and there is none Vignetting through the pupil of the patient's eye. Because the optical axes of the illumination and observation beam paths coincide behind the deflecting mirror, the illuminated and the observed area of the fundus are always concentric.

The deflecting mirror has a central opening, through which the doctor looks. The illuminating rays are only effective as far as they hit the deflecting mirror outside the central opening.

About the loss of light on the pupil the patient's eye if possible keeping it small, the optical imaging system creates the image of the light emitting area of the light source at a distance behind the opening of the deflecting mirror, which is approximately the same when using the device Distance between the cornea and the opening corresponds.

Because the beam expanding optical Component or prism similar therefore, how a plane-parallel plate acts leaves an axis-parallel the beam falling into the inner cone shows the component as expanded annular Bunch. In this way, the illuminating beam path becomes a hollow cone. Through the curvature of the cornea most of the reflected illuminating rays are from the optical Axle steered away. So you don't get into the beam cone, that hits the doctor’s eye. This hollow cone lighting maintains Moreover advantageous the Gullstrand'sche Principle of the separation of the illumination and observation beam path even with coinciding optical axes.

The device according to the invention stands out by bright illumination of the observation area and is suitable not just good for the direct but also for indirect ophthalmoscopy.

The beam expansion device expediently exists made of a transparent optically refractive material and is essentially cylindrical, being the light entry surface has the shape of a flat, inwardly facing cone shell and the light exit surface the shape of a flat, outward has directed cone jacket, the cone jacket on his perpendicular to the base facing away (rear) end in the form of a conic section can be flattened to the optical axis and have a flat circular surface can (Axicon).

To avoid disturbing reflections are preferred the outer peripheral surfaces of the Beam expansion device matt black. The beam expander can be located in a tube, the inner circumferential surfaces of which are matt black are, the space between the tube and the beam expansion device with an optically transparent substance with a refractive index similar to that Refractive index of the material of the beam expansion device is filled. Further, the flat rear end face of the beam expanding device and / or the outside the light entry surface located part of a front end surface be blackened.

An alternative embodiment of the Beam expansion device is characterized in that the beam expansion device from an inner conical mirror sitting on the optical axis and an outer concentric there is arranged toric mirror, which is a cutout from a conical Mirror is of the same angle and its axial positions in the beam path are so that radially inner end of the toric mirror in approximately the same axial position like the cone tip of the inner conical mirror and the radially outer end approximately in the same axial position as the base of the inner conical mirror is.

Advantageous with this beam design is that back reflections on the cornea of the patient's eye, not into the doctor's eye arrive when the illuminating beam path behind the beam expansion device centric to the optical axis within two pointed, coaxial bowling Coats (Hollow cone) runs, the tips of which lie on the cornea, with back reflections on the cornea run back inside the hollow cone.

According to a preferred embodiment the device according to the invention are the size of the light emitting Area of the light source and the imaging scale of the imaging system when imaging the light-emitting region of the light source chosen so that this Image of the light emitting area of the light source smaller than a circular area with a diameter of 2 mm. This application of the Köhler principle of lighting allows it, the illumination independently from the pupil diameter of the patient's eye.

The deflecting mirror in the illumination beam path can advantageously be arranged symmetrically to the optical axis and have an elliptical opening, which essentially corresponds to the shape of the projection cross section of the illumination beam path corresponds as well as with respect to the optical axis of the observation beam path is inclined. The mirror itself can also have an elliptical outer circumference to have. This can light weight and cheap Manufacturing costs for the deflecting mirror can be achieved.

Another advantageous embodiment the device according to the invention is a in the plane of the light field diaphragm near the optical axis area High contrast marking provided on a transparent support, where the transparent support is in the beam path or can be guided in and out of it. Such markings are also sharp as a fixing aid mapped the fundus.

In front of or behind the opening of the deflecting mirror there can be collecting or diverging, spherical or cylindrical lenses in the observation beam path can be introduced. In this way, the ametropia of the doctor or patient can be compensated.

Between the light source and the Luminous field diaphragm can be a short focal length lens with a high numerical aperture can be arranged, the light emitting Area of the light source approximately in the object-side focus the converging lens is located. this leads to to a high yield of the illuminating light emitted by the light source.

Appropriate image scales and a can make optimal use of light be guaranteed if between the light field diaphragm and the beam expansion device an imaging retrofocus lens system is arranged, the main planes are strongly displaced to the patient's eye. A simple one and inexpensive retrofocus lens system consists of a plano-convex and a biconcave lens, which in the Are spaced from each other. The plan-convex expediently point and the biconcave aspherical lens surfaces on.

As material for the converging lens, the beam expansion device, the short focal length converging lens and the retrofocus lens system transparent plastic is preferably used, whereby result in further cost advantages. The plastic can for example a polymethyl methacrylate.

A convenient light source is, for example a light bulb with a halogen gas filled Glass bulb. This can, for example, itself be designed as a converging lens his.

In the beam path of the ophthalmoscope according to the invention Polarization filter provided. As a result, the image quality and the Contrast can be improved.

The invention will continue in the following on the basis of a preferred exemplary embodiment which is not to be regarded as restrictive and the drawing explained. The drawing shows:

1 the representation of the beam path of a first embodiment of an inventive device (A) and the aperture image on the retina (B),

2 the function of in 1 illustrated axicons (A) and an alternative version with mirrors (B),

3 the optical imaging system in front of the Axicon,

4 the imaging beam path of a second embodiment of the invention and

5 the corresponding illumination beam path of the second embodiment of the invention, and

6 a schematic representation of the beam path of a known ophthalmoscope (A) and the aperture image on the retina (B).

It will start on 1 Referred. The device for observing the fundus of the eye shown there according to a first exemplary embodiment of the invention has the same reference numerals as that mentioned at the beginning in FIG 6 shown ophthalmoscope, insofar as the parts are the same as in the known embodiment of 1 are. Behind a light source 2 are a light field diaphragm 6 and an optical imaging system 8th . 10 arranged. This includes a converging lens 8th and a beam expanding axicon 28 , which is explained in more detail. Behind the axicon 28 is a deflecting mirror in the beam path 10 with a central opening 9 arranged. The deflecting mirror 10 is about 45 ° to the optical axis 4 inclined.

The deflecting mirror 10 points in the area of the optical axis 4 . 12 an opening 9 for the observation beam path. The observer sees through this opening with his eye 26 in the eye 16 of the patient. The optical axis 4 of the illuminating beam path falls behind the deflecting mirror 10 with the optical axis 12 of the observation beam path together so that the observer 26 a circular bright illuminated area 24 sees. He looks in the same direction in which the observation beam path extends after reflection. It can therefore use the entire illuminating beam intensity for observation on the fundus 18 be used.

The optical imaging system or the lens 8th has an appropriately adapted focal length and a corresponding distance from the light source 2 so the picture 14 of the light emitting area 3 the light source 2 behind the deflecting mirror 10 is produced. The picture 14 of the light emitting area of the light source 2 can through the imaging system 8th at a distance behind the opening 9 of the deflecting mirror 10 are generated, which is about the distance of the cornea 16 for opening 9 equivalent. As a result, the image becomes the light source 2 , especially their light emitting area 3 , created within the pupil of the eye. A diverging beam of rays is created behind the pupil, which means that the pupil does not affect the homogeneity of the illumination.

The focal length of the imaging system 8th and the magnification are chosen such that the image 14 of the light emitting area 3 the light source 2 is smaller than a circular area with a diameter of 2 mm. This value corresponds approximately to the minimum pupil diameter.

The already mentioned deflecting mirror in the illumination beam path has an elliptical shape. This shape corresponds approximately to the projection surface of the illuminating beam on the at an angle of 45 ° to the optical axis 4 inclined deflecting mirror 10 ,

The opening 9 is about in the middle of the deflecting mirror 10 and is also elliptical, being essentially the projection of the observation beam onto the mirror also inclined to the optical axis 10 equivalent.

In 2 is the axicon 28 shown more in detail as a prism version (A) and as a mirror version (B). It has a generally cylindrical shape and has a conical recess on the front side in the beam path 30 provided, with a flat ring surface 32 is released. The axicon points to the rear end in the beam direction 28 a central flat surface 34 on the outside of two conical surfaces that run obliquely backwards and outwards 36 is limited. The areas 32 and 36 are parallel to each other. The areas and 32 and 34 are blackened while the cylindrical outer surface 38 of the axicon 28 is matted, so that in the axicon through the surfaces 30 incoming light only on the surfaces 36 emerges and is otherwise absorbed or scattered. This is the example of the incoming beam cross section 40 illustrates that is circular. The emerging beam cross section 42 is ring-shaped, the incoming and outgoing rays are parallel to each other.

The beam expander according to 2 B) consists of an inner conical mirror sitting on the optical axis 60 and an outer toric mirror arranged concentrically thereto 62 , which is a section of a conical mirror with the same angle. The axial position of the two mirrors 60 . 62 in the beam path is chosen such that the radially inner end 64 of the toric mirror 62 approximately in the same axial position as the cone tip 66 of the inner conical mirror 60 and the radially outer end 68 of the toric mirror 62 roughly in the same axial position as the base 70 of the inner conical mirror 60 is.

3 illustrates the arrangement of a retrofocus system 40 that is in the beam path behind the object plane (F) 41 the light field diaphragm 6 is arranged. The Retrofo kus system includes a biconcave lens 42 and a plano-convex lens 44 , Its main levels, the object-side main level (H) 46 and its image-side main plane (H ') 48 are shifted to the right to the image plane at infinity. In this way, the desired imaging scale of the optical imaging system can be realized. The focal length of this system is approximately 11 mm in the exemplary embodiment shown.

4 and 5 illustrate the entire imaging and illumination beam path. 4 shows the image of the aperture on the retina and 5 the image of the filament on the pupil. Again, the parts already described are labeled with the same reference numerals as before. They are therefore not described in detail again. 6 shows a transparent carrier inserted into the beam path 50 with a marker 52 that serve as a fixation aid on the fundus 18 is mapped.

Claims (23)

Device for observing the fundus of the eye, in particular an ophthalmoscope, with an illumination and an observation beam path, wherein the illumination beam path in the direction of illumination comprises a light source, a collimator, a light field diaphragm, an optical imaging system arranged behind the light field diaphragm and a deflection mirror, the deflection mirror ( 10 ) in the area of the optical axis ( 12 ) an opening ( 9 ) for the observation beam path, - the optical axis ( 4 ) of the illuminating beam path in the illuminating direction behind the deflecting mirror ( 10 ) with the optical axis ( 12 ) of the observation beam path coincides, - the optical imaging system ( 8th . 40 ) a picture ( 14 ) of the light-emitting area of the light source behind the deflecting mirror ( 10 ) and - in the illumination beam path between the imaging system ( 8th . 40 ) and the deflecting mirror ( 10 ) a beam expansion device ( 28 ) is arranged, one to the optical axis ( 4 ) creates a central parallel offset in the illumination beam path and thereby the distance of light beams originally close to the axis to the optical axis ( 4 ) enlarged. Device according to claim 1, characterized in that the beam expansion device ( 28 ) consists of a transparent optically refractive material and is essentially cylindrical, the light entry surface ( 30 ) has the shape of a flat, conical surface facing inwards and the light exit surface ( 36 ) has the shape of a flat, outward-facing cone shell, the cone shell having a flat circular surface ( 34 ) having. Device according to claim 1 or 2, characterized in that that the Tapered casing in shape at its (rear) end facing away from the base of a conic section is flattened perpendicular to the optical axis (Axicon). Device according to one of claims 1 to 3, characterized in that the outer peripheral surfaces ( 38 ) of the beam expansion device ( 28 ) are matt black. Device according to one of claims 1 to 4, characterized in that the beam expansion device ( 28 ) is located in a tube, the inner circumferential surfaces of which are matt black and that the space between the tube and the beam expansion device ( 28 ) is filled with an optically transparent substance with a refractive index similar to the refractive index of the material of the beam expansion device. Device according to one of claims 2, 2 and 3, 2 and 4 or 2 and 5, characterized in that the flat rear end surface ( 34 ) of the beam expansion device ( 28 ) and / or the part of the front end surface located outside the light entry surface ( 32 ) is blackened. Device according to claim 1, characterized in that the beam expansion device consists of an inner conical mirror sitting on the optical axis ( 60 ) and an outer toric mirror arranged concentrically to it ( 62 ), which is a section of a conical mirror with the same angle and whose axial positions in the beam path are such that the radially inner end ( 64 ) of the toric mirror ( 60 ) in approximately the same axial position as the cone tip ( 66 ) of the inner conical mirror and the radially outer end ( 68 ) in approximately the same axial position as the base ( 70 ) of the inner conical mirror. Device according to one of claims 1 to 7, characterized in that the shadow cast by the flat circular surface or the inner toric mirror of the beam expansion device ( 28 ) essentially inside the opening ( 9 ) of the deflecting mirror ( 10 ) lies. Device according to one of claims 1 to 8, characterized in that the optical imaging system ( 8th . 40 ) the picture ( 14 ) of the light emitting area ( 3 ) the light source ( 2 ) at a distance behind the opening ( 9 ) of the deflecting mirror ( 10 ) which, when using the device, is roughly the distance between the cornea ( 16 ) and the opening ( 9 ) corresponds. Device according to one of claims 1 to 9, characterized in that the size of the light-emitting region ( 3 ) the light source ( 2 ) and the imaging scale of the imaging system ( 8th . 40 ) when imaging the light-emitting area ( 3 ) the light source ( 2 ) are selected such that the image (14) of the light-emitting region ( 3 ) the light source ( 2 ) is smaller than a circular area with a diameter of 2 mm. Device according to one of claims 1 to 10, characterized in that the deflecting mirror ( 10 ) is arranged symmetrically to the optical axis in the illumination beam path and has an elliptical opening ( 9 ) which essentially corresponds to the shape of the projection cross section of the observation beam path and with respect to the optical axis ( 12 ) of the observation beam path is inclined. Device according to one of claims 1 to 11, characterized in that the deflecting mirror ( 10 ) has an elliptical outer circumference. Device according to one of claims 1 to 12, characterized in that as a fixing aid in the plane of the light field diaphragm ( 6 ) near the optical axis ( 4 ) a flat marking ( 52 ) with high contrast on a transparent support ( 50 ) is provided, the transparent support being in the beam path or being able to be guided in and out of it. Device according to one of claims 1 to 13, characterized in that that as Ametropia compensation in front of or behind the opening of the deflecting mirror or distracting, spherical or cylindrical lenses can be introduced into the observation beam path are. Device according to one of claims 1 to 14, characterized in that between the light source ( 2 ) and the light field diaphragm ( 6 ) a short focal length converging lens ( 49 ) is arranged with a high numerical aperture, the light-emitting region ( 3 ) of the light source approximately in the focal point of the converging lens on the object side ( 49 ) is located. Device according to one of claims 1 to 15, characterized in that between the light field diaphragm ( 6 ) and the beam expansion device ( 28 ) as an imaging system ( 8th ) a collecting retrofocus lens system ( 40 ) is arranged, the outside optical main planes shifted to the image side ( 46 . 48 ) having. Device according to claim 16, characterized in that the retrofocus lens system ( 40 ) from a plano-convex lens ( 42 ) and a biconcave lens ( 44 ), which are spaced from each other. Device according to claim 15, characterized in that the short focal length converging lens ( 49 ) has aspherical surfaces. Device according to claim 17, characterized in that the plano-convex lens ( 42 ) and / or the biconcave lens ( 44 ) have aspherical surfaces. Device according to one of claims 1 to 19, characterized in that the beam expansion device ( 28 ) is made of a transparent plastic. Device according to one of claims 18 to 20, characterized in that the short focal length converging lens ( 49 ) is made of a transparent plastic. Device according to one of claims 16 to 21, characterized in that the retrofocus lens system ( 28 ) is made of a transparent plastic. Device according to one of claims 1 to 22, characterized in that that in Illumination and observation beam path polarization filter provided are.