DE3803305C3 - Device for detecting the focusing of a camera lens - Google Patents

Description

The invention relates to a device according to Preamble of claim 1, the z. B. from DE 33 29 603 A1 is known.

From US 46 36 624 the automatic detection of the focus of a photographic camera by the correlation method is already known. Fig. 1 shows schematically the optical system of such a device, which belongs, for example, to a single-lens reflex camera with automatic focusing. In Fig. 1, a photographic lens 1 , an object to be photographed 2 , a field of view mask 3 , a condenser lens 4 , an aperture mask 5 , a separator lens 6 , 7 as an optical image dividing element and a CCD element as an image receiving element are shown. The image field mask 3 , the condenser lens 4 , the diaphragm mask 5 . the separator lenses 6 and 7 and the CCD element 8 are integrated as one unit and form an optical system 9 for automatically detecting the focus.

In this system 9 , the field of view mask 3 is arranged close to an equivalent film plane 10 . This equiva lent film plane 10 is in an optically conjugate position to the object 2 to be recorded by the lens 1 . A sharply focused image 11 of the object 2 is generated on the equivalent film plane 10 when the lens 1 is in focus. The condenser lens 4 and aperture mask 5 eliminate edge light, which passes the lens 1 right and left. The separator lenses 6 and 7 are in an optically conjugated position to the lens 1 via the condenser lens 4 .

The separator lenses 6 and 7 are, as shown in FIG. 2, horizontally next to each other. Furthermore, they are ima ginary opening areas 14 and 15 of an exit pill 13 of the lens 1 opposite and "look" through a zone 12 , which is optically conjugated to the central zone of a viewfinder in a manner still to be described. The separator lenses 6 and 7 receive a beam of rays that passes through the opening areas 14 and 15 . The image 11 generated on the equivalent film plane 10 is shown in the form of two images 11 'on two areas of the CCD element 8 .

The distance between the two images 11 ', which results in focus (see Fig. 3a) in FIG. 4 designated by _O L. If the lens 1 is focused in front of the equivalent film plane 10 , as shown in FIG. 3b, the distance between the images 11 'is short, so that the distance between two corresponding signals S is also shorter than the distance l ₀ . On the other hand, if the lens 1 is focused behind the equivalen th film plane 10 , as shown in FIG. 3c, the distance between the images 11 'is longer, so that the distance between corresponding signals S is longer than the distance l ₀ . Since the distance between the images 11 'changes proportionally to an incorrect setting of the objective 1 , the distance between the images on the CCD element 8 is evaluated in the known device for detecting the focus in a single-lens mirror camera, and these correspond to the signals are processed arithmetically. Then, the lens 1 is moved depending on the focus direction and the misadjustment amount of the lens 1 to the correct focus position. In the example shown in FIG. 5, the optical focusing is carried out via the viewfinder image, with an object 2 to be recorded being assigned in the central zone 17 of the viewfinder 16 . The lens 1 is automatically in focus. Then, when the picture is taken, the image is well focused.

Since in this known device in a single-lens reflex camera, the focusing zone 17 is arranged in the center of the viewfinder image 16 , an object to be recorded 2 , which has been brought into focus, will appear in the middle of a photograph unless special measures are taken to circumvent this before are. However, there are cases in which an object 2 should preferably appear in the edge area of a photograph and not in the middle. For this purpose, a storage mechanism for holding the focus adjustment is provided in known single-lens reflex cameras. The object 2 to be recorded is first brought into the center of the viewfinder 16 in order to carry out the automatic distance setting. In this state, the setting is held. If a picture with an image distribution corresponding to FIG. 6 is then desired, it can be easily undertaken, and the object 2 is then in the edge region of the image.

Here, however, the object 2 must first appear in the center of the viewfinder 16 . Then the lens 1 must be focused. This setting must then be held to fix the lens 1 . Then the image distribution is carried out again. Only then can the picture be taken. So it takes a lot of time and effort before the camera is ready to take a picture.

So it would be desirable if the focus not only for a medium range of the viewfinder image, but also for an edge area could be detected. However, there would be several of them Systems of the type described are required.

The known device mentioned at the beginning contains several image dividers, but these only form each the same zone of the object image on a light sensitive Chen arrangement and serve to collectively Increase system sensitivity.

It is an object of the invention to provide a device for Detecting the focus of a camera lens specify with which it is possible to focus not only for a medium range, but also for capture other areas of the viewfinder image.

The invention solves this problem through the feature le of claim 1. Advantageous further developments are specified in the subclaims.

In a device according to the invention different zones of the object image on the light temp sensitive arrangement shown. This makes it possible Lich, the focus for these different Zo to capture. Through the construction of everyone Image splitter with two separator lenses are on the associated with each image divider photosensitive Arrangement produces two similar images that the Er focus in a zone of the viewfinder allow the arrangement of each Corresponds image splitter relative to the optical axis.

If the separator lenses in a device after the invention not with predetermined angles of Face exit pupil, so the Auswer Accuracy worse due to vignetting. That's why the angle of the separator lenses must be that of the exit Face pupil of the lens, correspond respectively according to the lens property (e.g. short or long focal length) if that  Lens is changed. This enables the next education of the invention according to claim 2.

With the training according to claim 4 or 8 the optical axis of the device for determining the Mechanical and automatic focusing on the center the exit pupil of the lens can be adjusted even if this against a lens with another Focal length is changed in which the attachment process of the lens is exploited. Everyone will Impaired by vignetting avoided.

Embodiments of the invention are in fol genden explained in more detail with reference to the drawing. In one individual shows

Fig. 1 is a schematic representation of a known device for determining the focusing,

Fig. 2 is a perspective view of the device shown in Fig. 1 schematically

Fig. 3 is a schematic representation of the nen Various settings in a lens,

Fig. 4 shows the output signals of a CCD element accordingly the settings of FIG. 3rd

Fig. 5 is a schematic illustration of a search for a device Erbil of known type,

Fig. 6 is a schematic representation of a search of the previous Erbil for explaining the recording technique type for an object in the edge region of the image,

Fig. 7 to 10 are schematic diagrams for Erläute tion of a first embodiment of the invention,

Fig. 11 to 20 are schematic diagrams for Erläu esterification of a second embodiment of the OF INVENTION dung, and

Fig. 21 to 23 are schematic diagrams for Erläu esterification of a third embodiment of the dung OF INVENTION.

In Fig. 7 to 10, a first embodiment is ei ner means for automatically detecting the Fo kussierung for a single lens reflex camera is provided. Fig. 7 shows schematically the optical system of this device. Such elements, which correspond to the elements of the already known device, have the same reference numerals as in FIGS. 1, 2 and 3. It is shown in solid lines via an exit pupil 13 of the objective 1 , which can be viewed by a zoomer 12 of an automatic optical focus system 9 corresponds, which is also referred to below as an autofocus system. The exit pupil 13 has a circular shape, as also shown in FIG. 9. The opening areas 14 and 15 have an elliptical shape when viewed through the separator lenses 6 and 7 .

In this first embodiment, the autofocus system 9 is provided on both sides with optical autofocus edge systems 18 and 19 , which serve to evaluate an optical area corresponding to the edge area of the image. The Autofokussy stem 18 consists essentially of two Separatorlin sen 20 and 21 as optical dividing elements and a CCD element 22nd The other autofocus system 19 consists essentially of two separator lenses 23 and 24 as optical dividing elements and a CCD element 25 .

A mounted on the camera housing viewfinder 16 , as shown in Fig. 8, has on both sides of a central zone 17 edge zones 26 and 27 , which correspond to the auto focus edge systems 18 and 19 . The edge zones 26 and 27 are optically conjugated to the zones 28 and 29 of the autofocus systems 18 and 19 .

Fig. 7 shows that the separator lenses 20 and 21 and the separator lenses 23 and 24 are adjacent to each other in the vertical direction. The separator lenses 20 , 21 , 23 and 24 are arranged via a condenser lens 4 , which is not shown in FIG. 7, optically conjugate to the exit pupil 13 of the objective 1 and see opening areas 30 and 31 through the zones 28 and 29 in a vertical alignment the exit pupil 13 . The separator inserts 23 and 24 are arranged vertically one above the other for the following reasons. A bundle of rays that falls through the lens 1 onto the zones 28 and 29 becomes an oblique bundle of rays. The exit pupil 13 of the objective 1 , when viewed through the zones 28 and 29, has a flattened shape, as shown in FIG. 10, due to the vignetting. If the opening areas 30 and 31 were horizontally next to each other, the baseline between the separator lenses 20 and 21 (separator lenses 23 and 24 ) would not be long enough. The result would be poor lens performance and poor evaluation accuracy of the object distance.

In Fig. 7, the optical axis of the objective 1 is designated by 1 . Furthermore, the central optical axis l _{1 of} the auto focus system 18 and the corresponding optical axis l _{2 of} the auto focus system 19 are shown. These axes l ₁ and l ₂ intersect in the middle O _{1 of} the exit pupil 13 . There are also the optical axis l _{11 of} the separator lens 20 , the optical axis l ₁₂ of the separator lens 21 , the optical axis l _{21 of} the separator lens 23 and the optical axis l ₂₂ of the separator lens 24 . The optical axes l ₁₁ and l ₂₁ intersect in the middle O _{2 of} the opening area 31 , while the optical axes l ₁₂ and l ₂₂ intersect in the middle O _{3 of} the opening area 30 .

As a result, the edge zones 26 and 27 are arranged on both sides of the central zone 17 of the viewfinder 16 , and the autofocus edge systems 18 and 19 are arranged accordingly the edge zones 26 and 27 . If the CCD elements 8 , 22 and 25 are controlled according to the zones 17 , 26 and 27 ( FIG. 8) that can be selected, the distance to the object 2 can be automatically with the autofocus systems 9 , 18 and 19 accordingly, the selection of one of the zones 17 , 26 and 27 can be determined. Zones 17 , 26 and 27 are selected manually or automatically.

Another embodiment of a device for automatically determining the focus for a single-lens reflex camera is described below with reference to FIGS. 11 to 20.

Referring to FIG. 12 may be generally ring B ₁ A ₁ to a camera body attached to and detached from an interchangeable lens. Two cases will be considered here: firstly, the lens 32 attached to the lens ring B ₁ should have a long focal length according to FIG. 20, and secondly the lens 33 should have a short focal length according to FIG. 19.

In this case, the optical axes l ₁ and l _{2 of} the autofocus edge systems 18 and 19 have different angles Θ ₁ between the optical axes l ₁ , l ₂ and the optical axis l. As shown in FIG. 11, the angles of the separator lenses 20 , 21 , 23 and 24 , which are directed towards the exit pupils 13 and 34 of the lens 1 , must be changed depending on whether an arrangement 33 with a short focal length or a is used as the lens 1 Anord voltage 32 is provided with a long focal length, and the optical axis l of the lens 1 and the optical axes l ₁ and l _{2 of} the autofocus systems 18 and 19 must be different. The impairment due to vignetting is taken into account when the opening areas 35 and 38 of the exit pupil 34 of the objective 1 with an arrangement 32 with a long focal length are opposite the separator lenses 20 and 21 of the autofocus system 18 and when the opening areas 36 and 37 of the exit pupil 34 face the separator lenses 23 and 24 of the autofocus system 19 face each other. In Fig. 11, the opening areas of the exit pupil 34, which are associated with the separator lenses 6 and 7 are designated by 39 and 40.

As is apparent from Fig. 12, in front of an autofocus unit 50 , which is located in the camera housing A ₁ and forms the autofocus systems 9 , 18 and 19 , an optical element 51 is arranged with which the angle of the separating lens 20 , 21 , 23 and 24 of the autofocus edge systems 18 and 19 are changed, which stand against the lens. The optical element 51 changes the angle so that the direction of the beam picked up by the autofocus systems 18 and 19 is adapted to the direction of the exit pupil of the objective 1 . The optical element 51 has, as shown in FIGS . 13 and 15, the shape of a cylindrical plate. It is made in one piece from plastic, for example.

The optical element 51 has a central transparent portion 52 with a uniform thickness near the autofocus system 9 and a prismatic portion 53 which encloses the central central portion 52 in an annular manner. The prismatic portion 53 has, as shown in Fig. 16 to 18, transparent parts 54, each having a uniform thickness and prismatic parts 55 and 56. These have a greater thickness on the outer circumference than on the inner circumference. The tip angles of the prismatic parts 55 and 56 are different as shown in Figs. 16 and 18. In the following, the function of the prismatic section 53 will first be described, since after a rotary element 57 for holding the optical element 51 will be explained.

In this exemplary embodiment, the rotating element 57 according to FIG. 13 is rotatably mounted on four rollers 58 . The rotary member 57 is shown in FIG. 14 ßenumfang provided at its Au with a guide groove 59 for guiding the rollers 58. The rollers 58 are each arranged on an axis 59 which, for. B. is attached to a shield plate 60 in which an opening 61 is provided.

The rotating member 57 is rotated by a motor 62 ge. It is provided on its outer circumference with a toothing 65 , in which a pinion 64 engages on the shaft 63 of the motor 62 . The motor 62 is controlled by a driver amplifier 66 , which in turn is controlled by the commands of a microprocessor 67 . Upon receipt of information from a lens fixed value memory 68 which is assigned to the lens ring B ₁ , the microprocessor 67 controls the driver amplifier 66 . FIG. 12 shows a connecting pin 69 which is arranged on the lens ring B ₁ . Furthermore, a connection 70 is provided on the camera housing A ₁ . An opening 71 is also shown in FIG .

If the lens ring B ₁ with the lens 33 with a short focal length is attached to the camera housing A ₁ , the microprocessor 67 drives the motor 62 in such a way that the transparent part 54 with a uniform thickness faces the zones 28 and 29 , as in FIG Figure shown. 19th If the lens ring B ₁ with the lens 32 with a long focal length is attached to the camera housing A ₁ , the microprocessor 67 controls the motor 62 such that the prismatic part 56 faces the zones 28 and 29 , as shown in FIG. 20 ge shows is. Then the microprocessor 67 stops the rotary element 57 in this position.

This automatically changes the angle of the separator lenses 20 , 21 , 23 and 24 of the autofocus edge systems 18 and 19 , which face the exit pupil of the lens 1 .

So if, for example, the lens ring B ₁ with the lens 33 short focal length is released from the camera housing A ₁ and if the lens ring B ₁ with the lens 32 long focal length is attached to the housing rage A ₁ , then the optical element 51 is around an imaginary center Z ₁ ( Fig. 13) rotated, and the prismatic section 56 is stopped in a position in which it faces the zones 28 and 29 ge. As a result, the angles of the separator lenses 20 , 21 , 23 and 24 , which face the exit pupil of the objective 1 , are automatically changed from zu ₁ to Θ ₁ '. When the prismatic part 55 faces the zones 28 and 29 , the angles of the separator lenses 20 , 21 , 23 and 24 which face the exit pupil le of the objective 1 are changed to values other than und ₁ and ' ₁ ', so that an adaptation to a lens with a different focal length results.

In this embodiment, the micro processor 67 controls the motor 62 upon receipt of information from the lens read only memory 68 associated with the lens ring B ₁ . Even if the information of the read-only memory 68 is not available, however, the rotary element 57 can be continuously rotated by the microprocessor 67 as soon as the lens ring B _{1 is} attached to the camera housing A ₁ . Then, the rotating position in which the amount of light falling on the CCD elements 22 and 25 becomes maximum can be determined by the microprocessor 67 and the rotation of the rotating element 57 can be stopped, so that the angles of the separator lenses 20 , 21 , 23 and 24 , the facing the exit pupil of lens 1 , are automatically changed from Θ ₁ to Θ ₁ '.

In the embodiment described above two prismatic parts are used. The However, the invention is not limited to this.

In this embodiment, the zone of the autofocus system is arranged in an optically practically conjugated position with respect to the central zone of the viewfinder, which is located on the camera housing A ₁ . Another zone is seen in the edge area of the viewfinder. A zone of the autofocus system is ragehäuse edge in a virtually optically conjugate position in Kame A ₁ disposed on the edge zone. If a photograph of an object is to be taken that is not in the center of the viewfinder image, the distance to the object can be found automatically without cumbersome operation by using the autofocus edge system. If the lens is focused by movement on the lens ring, the direction of the beam automatically picked up by the autofocus edge system can be regulated and adjusted so that it corresponds to the direction of the exit pupil of the lens, which is located on the camera body.

In the following, a third embodiment of a device for automatically detecting the focussing of a single-lens reflex camera is described with reference to FIGS . 21 to 23.

In the embodiment shown in FIG. 21, the angle between the optical axis l of the objective 1 and the optical axes l ₁ and l _{2 of} the optical autofocus systems 18 and 19 is changed mechanically. A device 141 serves this purpose.

The camera body A ₁ contains a housing 142 in a predetermined position, on whose two sides further housings 143 and 144 are arranged. The housing 142 contains the autofocus system 9 . Housings 143 and 144 contain autofocus systems 18 and 19 .

The device 141 for automatically changing the angle of the optical axis includes two bearing axles 145 and 146 which are coaxially attached to the upper and lower surfaces of the housing 143 and two bearing axles which are similarly attached to the upper and lower surfaces of the housing 144 . These bearing axes 145 and 146 as well as 147 and 148 are fastened to a holding plate (not shown) of the camera housing A _{1 in} such a way that they lie parallel to the equivalent film plane 10 and can be moved to the right and left with respect to the illustration in FIG. 21. The bearing axles 145 and 146 as well as 147 and 148 are also rotatable. As a result, the housings 143 and 144 can be moved relative to the housing 142 and rotated about the respective axis, as shown by arrows 149 and 150 .

Furthermore, the device 141 for automatically changing the angle of the optical axis includes a mechanical drive 153 (jointly moving mechanical elements) which engages in an engagement hole (engagement part) 152 on the lens ring B _{1 of} the lens 1 when it is on the camera housing A. _{1 is} fixed so that the bearing axes 146 and 148 are rotated according to the focal length of the lens 1 and the optical axes l ₁ and l _{2 of} the autofocus edge systems 18 and 19 and the zones 28 and 29 are aligned with the center of the exit pupil of the lens 1 will.

The mechanical drive 153 has articulated members 154 and 155 , one end of which is attached to the lower ends of the bearing axles 146 and 148 , and an axle 156 , on which the other ends of the articulated elements 154 and 155 are connected to one another. The axis 156 is arranged so that it is perpendicular to the optical axis l, and held in the camera housing A ₁ so that it can be moved back and forth in the direction of arrow 156 a, ie in the direction of the optical axis l. Furthermore, the mechanical drive 153 comprises a Antriebssele element 157 , one end of which is rotatably held on the axis 156 and the other end of which carries an engagement pin 158 which protrudes from the camera housing A ₁ . A spring 159 biases the drive element 157 in the direction opposite to the axis 156 , ie in the direction in which the engagement pin 158 protrudes from the lens mount (not shown) of the camera housing A ₁ .

When the lens ring B _{1 of} the lens 1 is attached to the camera body A ₁ , the gripping pin 158 comes into the engaging hole 152 , and its front end abuts the bottom of the engaging hole 152 . The engagement pin 158 can be moved back and forth parallel to the optical axis 1. The engaging hole (engaging part) 152 , in which the engaging pin 158 engages, is formed so that its depth D is smaller with a shorter focal length of the lens 1 . Furthermore, the depth of the engagement hole 152 is dimensioned such that when the lens ring B _{1 of} the lens 1 is attached to the camera housing A _1, the engagement pin 158 can engage and the optical axes l ₁ and l _{2 of} the autofocus edge systems 18 and 19 and the zones 28 and 29 can be set to the center of the exit pupil of the objective 1 by the mechanical drive 153 . Fig. 22 shows in the upper part of one example of the depth D of the engaging hole 152 with a long focal length of the lens 1, while the lower part of another example of the depth D shows the engaging hole 152 with a short focal length of the lens 1.

Thus, when the lens ring is B ₁ of the lens 1 to the camera body A _{1 is} attached, so engages the engagement pin 158 into the engaging hole 152, and the amount extending around the engagement pin 158 housing of the camera A _1, is the engagement hole 152 changed according to the focal length of the lens 1 . The drive element 157 is moved back and forth in the direction of the optical axis 1. As a result, who pivoted the articulation elements 154 and 155 about the respective bearing axis 146 and 148 . As a result, housings 143 and 144 are again pivoted about bearing axes 146 and 148 , and at the same time axes 146 and 148 are moved towards or away from one another. This moves the end portions of housings 148 and 144 , ie the sides where zones 128 and 129 are located, towards or away from each other. The optical axes l ₁ and l _{2 of} the autofocus edge systems 18 and 19, the zones 28 and 29 are thereby automatically set to the center of the exit pupil of the objective 1 .

As described above, this one is Embodiment the zone of optical autofocus systems in an optically conjugated position against over the middle zone. That on the camera body Interchangeably attached lens is off output signal of the light-receiving element of the car focus system moved to focus. Other Border zones are on both sides of the central zone of the Viewfinder image arranged. The autofocus zone Edge system is in an optically conjugated Position to the edge zone. The optical axes of the at the autofocus edge systems and their zones largely to the middle of the exit pupil of the ob jective through the engaging part and through the mechanical coordinated movement of the mechanical elements set when the lens is attached to the camera body is increased. The engagement part can on the mirror cylinder Lens provided. By this arrangement can be the inclusion of an object that is not in the Image center located can be done quickly by the distance with the auto focus edge system auto is set mathematically. So this is not a hassle Recording process required. This also applies to Use a lens with a different focal length. In this case, the optical axis of the autofocus Edge system automatically to the center of the exit pu pill of the lens when attaching the lens to Camera body set. Thus becomes a leg Prevention of vignetting automatically avoided the.

Claims (9)

1. Device for detecting the focusing of a camera lens, in which the object image obtained in an equivalent film plane is divided into several object images conjugated to the exit pill of the camera lens and divided into further object images and these are each imaged on a light-sensitive arrangement assigned to an image divider which can be selected to detect the focus, where

• 1. an inner image divider is provided for the central image area, which consists of two separator lenses which are arranged symmetrically to the camera lens in the area of the optical axis thereof, and
• 2. outer image dividers are provided for each edge area of the images and are arranged symmetrically to the optical axis of the camera lens, which likewise each consist of two separator lenses which are arranged transversely to the direction of the optical axis in such a way that the connecting straight lines of the lens centers of the respective outer image dividers are perpendicular on that of the separator lenses of the inner image divider.

2. Apparatus according to claim 1, characterized in that on the equivalent film plane ( 10 ) a direction arrangement ( 51 , 141 ) is arranged which the direction of the optical axes (l ₁ , l ₂ ) of the further image dividers ( 20 , 21 ; 23 , 24 ) according to the distance between these image splitters and the exit pupil of the camera lens. 3. Apparatus according to claim 2, characterized in that the direction arrangement ( 51 , 141 ) for changing the direction of the optical axes (l _1, l ₂ ) is adjustable. 4. Apparatus according to claim 2 or 3, characterized in that the directional arrangement an optical element ( 51 ) with a central, on the optical axis (l) of the camera lens ( 1 ) lie the plane-parallel part ( 52 ) and at least two symmetrical to it the optical axes (l ₁ , l ₂ ) of the further image dividers ( 20 , 21 ; 23 , 24 ) is arranged prismatic parts ( 55 , 56 ). 5. The device according to claim 4, characterized in that the optical element ( 51 ) on the op table axis (l) is rotatable to the prismatic parts ( 55 , 56 ) optionally on the optical axes (l ₁ , l ₂ ) the further image divider ( 20 , 21 ; 23 , 24 ) to arrange. 6. The device according to claim 4 or 5, characterized in that the central part ( 52 ) of the optical element's ( 51 ) is cylindrical, and that the prismatic parts ( 55 , 56 ) surrounding the central part ( 52 ) ring ( 53 ) form. 7. The device according to claim 6, characterized in that the ring ( 53 ) diametrically opposed to each other has transparent plane-parallel parts ( 54 ). 8. The device according to claim 2 or 3, characterized in that the directional arrangement ( 141 ) for each further image splitter ( 20 , 21 ; 23 , 24 ) with associated photosensitive arrangement ( 22 , 25 ) comprises a housing ( 143 , 144 ), the one of the exit pupil of the camera lens ( 1 ) facing light entry opening ( 28 , 29 ) and on a par allel to the equivalent film plane ( 10 ) lying axis ( 145 , 146 ; 147 , 148 ) is rotatable. 9. The device according to claim 8, characterized in that a mechanical drive ( 153 ) for the housing ( 143 , 144 ) is provided, which is movable by the camera lens ( 1 ) into a position in which the optical axes (l ₁ , l ₂ ) of the further image dividers ( 20 , 21 ; 23 , 24 ) are directed towards the exit pupil of the camera lens ( 1 ).