DE2254446A1 - DISTANCE METER - Google Patents

Description

Range finder The invention relates to a range finder For lenses that are in focus between at least two lens elements have a practically parallel beam path, in particular varifocal lenses, A rangefinder for such lenses is already known, in which in the area with a parallel beam path is a rectangular glass part with a rectangular shape is arranged to the optical axis of the lens oriented surfaces, wherein within the glass part-two inclined, spaced-apart partially transparent mirror surfaces are arranged.

Such a rangefinder is relatively difficult in the production, since it consists of several glass elements, the edge angles are very must match exactly in order not to generate measurement errors. This rangefinder also has the disadvantage that in the optical path of the lens a - albeit very weak - Double image is generated.

The invention is based on the object of a range finder to create the type mentioned, which can be manufactured inexpensively and the no double images generated in the lens beam path.

The solution to this problem is to be seen in the fact that im. Area of parallel beam path at least two mirror elements arranged are, which are perpendicular to the optical axis of the lens at a distance from each other and which are oriented with their mirror surfaces essentially parallel to one another are that the reflected rays are directed into a collecting seeker system, whose view forms the rangefinder view.

The reflection angles of the parallel rays are preferably on the mirror surfaces and the position of the same chosen so that of a mirror element reflected rays do not fall on another mirror element. At right-angled This can be achieved by deflecting the beams in that the mirror elements arranged offset from one another in the direction of the optical axis of the lens are.

According to a further development, the inclination of the mirror elements is relative to one another adjustable to reduce the influence of a slight deviation from a parallel To be able to compensate the beam path.

The mirror elements can according to a special Ausrührungsrorm Be part of an essentially plane-parallel, transparent plate. Since such Easily manufacture and mirror plates with great accuracy is one rangefinder built with it and very inexpensive with high accuracy.

Preferably, the mirror surfaces are transverse to the optical axis of the Objective as great a distance from each other as possible, since this distance is a measure For the basis of the range finder, the measuring accuracy of the same is determined.

When using a substantially plane-parallel, transparent one Plate, the mirror surfaces can be applied to them as surface mirrors.

According to a further development of this embodiment, one forms Mirror element a partially reflective mirror on the front surface of the Plate and the other mirror element on a fully reflective mirror the back surface of the same. This makes a compact, robust and very allows accurate construction of a range finder.

The front surface of the plate can correspond to a geometric Patterns, for example stripes or checkerboard-like, partially reflective mirrored, so that there are more than two mirror elements and when the setting is out of focus multiple images result from the lens.

The mirror elements are preferably colored differently in order to Different colored double or multiple images with blurred lens mount to create.

Overall, the mirror elements should have such a large surface area that they are at most 50% and preferably at most 20% of the parallel rays hide the optical path of the lens so as not to reduce the light output of the lens to weaken too much.

The mirror elements can also be removed from the beam path for the same purpose of the lens can be moved out.

The range finder is preferably included in a reflex finder system especially for film cameras, since here only the one known per se Masking mirror for masking out part of the parallel rays of the lens needs to be replaced by the mirror element arrangement according to the invention.

The parts of the plane-parallel, transparent plate are preferably provided with an anti-reflective coating.

The range finder according to the invention is suitable for all lenses of recording devices such as cameras, film cameras, television cameras, which have a parallel beam path at any point in their beam path when in focus.

Under a finder system is a lens link or a combination the same to understand which - possibly under image reversal - one with the lye observable image designs.

The invention is described below with reference to schematic drawings described in addition to several exemplary embodiments.

Fig. 1 is an axial section through a varifocal lens for a film camera with a range finder according to the invention, which also serves as a viewfinder.

2 is a sectional view through a plane-parallel glass plate, on the surface of which the mirror elements are applied.

3a to 3c show different patterns of the surface mirroring a transparent glass plate.

4 shows another embodiment of the mirror element arrangement according to the invention.

Figure 1 shows a varifocal lens for a film recording camera with a ~ Distance meter according to the invention.

The lens consists of a vario part 2 with a distance setting ring 1 and a basic lens 3 behind it, behind which there is a fixed stage 4 of the movie camera is located. The film stage serves as a support for an unexposed one Movie.

When focusing, the varifocal lens points between the vario part 2 and the basic objective have a parallel beam path. In this area lies a distance measuring element which is inclined with respect to the optical axis of the objective 6, which consists of a plane-parallel, transparent glass plate, the front Surface 13 partially reflective and its rear surface 14 completely is reflective. The range finder is at a 450 angle inclined to the optical axis so that the reflected rays are perpendicular to the optical axis and arrive in a viewfinder lens 7 and from there over a deflecting mirror 8 into an erecting lens system 9, through an image mask 10 and through eyepiece members 11 through which the image can be perceived with one eye 12 can.

In the present description, those from the viewfinder lens 7, the lens system 9 and the ocular members 11 lens members as a whole referred to as the viewfinder system. Any other lens system can also be used, with which it is possible to choose from the essentially parallel rays emanating from the Distance measuring element 6 are hidden, an image that can be observed with the eye produce.

The distance measuring element 6 consists of a plane-parallel, transparent Glass plate that is partially reflective on its front surface and partially reflective on its rear surface The surface is completely reflective.

This distance measuring element can be seen from the beam path of the lens be pivoted out, as shown in Fig. 1 by the curved arrow.

As can be seen from Fig. 2, each ray of light is upon impingement split into two beams on the range finder. E.g. the light beam becomes 15 reflected in one part on the front surface of the glass plate Light beam 15 ', while the remaining part of the light beam 15 penetrates the glass plate, is reflected on the fully mirrored rear surface and then as a ray of light 15 ", which is offset parallel to the reflected beam 15 ', the glass plate again leaves. The same thing happens with each ray of light at a different point in the Glass plate, for example with the light beam 16, which is split into the partial beams 16 'and 16 " will.

As long as the incident radiators, about 15 and 16, are parallel to each other run, the splitting of the individual rays has no influence on the with image observed through the eyepiece.

However, any imprecise focus setting of the lens will result in that the rays falling at different points on the glass plate are no longer are parallel to each other.

Assume that the light beam 15 is parallel to the optical axis of the lens, it naturally does not change its angle of incidence. Every light beam that does not come in parallel to the optical axis falls accordingly a certain tendency to the same, as indicated by the light beam 16a is. Those reflected at this point Rays 16a 'and 16a "are still parallel to each other, but not parallel to the rays 16 ' and 16 ''. This results in a double image or a blurred image that is different from the Angular displacement of the partial beams 16a 'and 16asz to the partial beams 16' and 16 " originates.

The expansion of the glass plate is preferably smaller than the cross section of the parallel bundle of rays, otherwise the distance measuring element would be removed during the exposure would have to swing out of the beam path.

A double image or multiple image structure that is particularly easy to perceive results when 'the front surface of the glass plate according to the patterns is partially mirrored according to Figures 3a, 3b or 3c. The surface or the mass of the glass plate must be colored so that the double or multiple images in different colors appear, for example in complementary colors, which are different with correct Complement the distance setting to the natural color.

Fig. 4 shows another embodiment of a distance measuring element, in which the mirror elements are not on one, but on two separate ones; Glass plates are attached> which are in different levels - The individual glass plates only need to be mirrored on the front surface.

The invention can be understood within the scope of the general idea of the invention can still be implemented in various other designs and is not limited to these exemplary embodiments limited.

Claims (12)

PATENT CLAIMS Q1 Rangefinder for camera lenses that are in focus a practically parallel beam path between at least two lens elements have, in particular varifocal lenses, characterized in that at least two mirror elements (13, 14, 17, 18;) are arranged at right angles to the optical axis of the lens a Have a distance from each other and the mirror surfaces are essentially parallel are oriented to each other and so that the reflected rays in a convergent Viewfinder system (7,9,11) are steered, the view of which is the rangefinder forms. 2. Distance meter according to claim 1, characterized in that the mirror elements against each other in the direction of the optical axis of the lens are arranged offset. 3. Distance meter according to claim 1 and 2, characterized in that that the mirror elements (17, 18) are adjustable to one another. 4. Distance meter according to claim 1 and 2, characterized in that that the mirror elements are part of a substantially plane-parallel, transparent Plate (6) are. 5. Distance meter according to claim 1 and 4, characterized in that that the mirror surfaces transverse to the optical axis of the lens are as large as possible Have a distance from each other. 6. Distance meter according to claim 4 or 5, characterized in that the mirror surfaces are applied to the plate (6) as surface mirrors. 7. Distance meter according to claim 6, characterized in that the one mirror element has a partially reflective mirror (13) on the front Surface of the plate (6) and the other mirror element a fully reflective Forms mirror (14) on the rear surface thereof. 8. Distance meter according to claim 4 to 6, characterized in that that the front surface of the plate (6) corresponds to a geometric pattern, is roughly strip-like or checkerboard-like, partially reflective. 9. Distance meter according to claim 1 to 8, characterized in that that the mirror elements are colored differently. 10. Distance meter according to claim 1 to 1, characterized in that that the mirror elements as a whole have such a large surface that they at most 50% and preferably at most 20% of the parallel rays from the beam path of the lens. 11. Distance meter according to claim 1 to 1o, characterized in that that the mirror elements can be moved out of the beam path of the lens. 12. Distance meter according to claim 1 to 11, characterized in that that the parts of the plate (6) not provided with mirror surfaces have an anti-reflective coating are provided. Blank page