SU1130827A1 - Device for lens focusing - Google Patents

Abstract

1. DEVICE OF LENS OF FOCUSING THE LENS, containing a focused lens, a sighting device, a reflecting mirror, a beam-splitting element installed near the plane adjacent to the focusing plane of the lens, and forming two optical channels, each with a multi-element light receiver, and a unit : signal processing with comparators, at the output of which a precision focus position indication device is turned on, characterized in that, in order to increase the focusing accuracy, a revision has been introduced into it The optical optical system located in one of the optical channels behind the beam-splitting element, the image plane behind which is located at an equal distance from the division plane and conjugated with the focusing plane of the imaging lens, combined with the object plane of the inverting optical system, in the image plane of which the multi-element light receiver is located , moreover, the corresponding elements of each multi-element light receiver are pairwise connected to the signal processing unit. . 2. The device according to any one of the preceding paragraphs, which, in order to reduce its size, the reversing system is made in the form of a prism block with three reflective edges, the lenses are mounted on the input and output edges, 3. The device according to .1, characterized in that in the signal processing unit, the elements of the beam element light receivers are pairwise connected to the inputs of the comparators, the outputs of which are connected to the input of the input unit AND, the output associated 00 with the indicator. o 4. Device according to nn. 1, and 3, o; t 00 that the outputs of the 53 comparators are connected to the input of the entered adder, the output of which through the entered additional comparator is connected to the indicator.

Description

The invention relates to photographic equipment, namely, cameras with automatic or semi-automatic focusing of the lens, and can also be used in other devices where focusing of the lens on an object of arbitrary shape is required. A device for focusing a lens using a distance-ranging focusing principle is known, in a biaxial rangefinder of which there are two linear arrays 1 photodetectors on which an image is projected from two branches of a rangefinder. In one of the branches there is a swinging mirror, which, when the lens is focused, moves until the image on both arrays of photodetectors is ideological .flj. The use of a moving element. (Mirrors / for combining images complicates the focusing device and makes it practically inapplicable in single-lens reflex cameras. The closest in technical essence to the invention is a device for focusing a lens containing a focused lens, a sighting device, a reflecting mirror, a beam-splitting element installed near the plane adjoining to the focusing plane of the lens and forming two optical channels, each of which has many an elementary light detector, as well as a signal processing unit with comparators, the output of which includes an indication device. of a precise focusing position. The main part of the device is a plane-parallel plate, which has a luminous surface and serves for obtaining two images that are shifted relative to each other along optical axes at a certain distance. Two images fall on two lines of photodetectors, the signals from which are used to determine and indicate the position of precise focusing. The focusing principle is based on the analysis of the contrast of the image obtained by the lens. In this system, the signals are compared (their differences I are found from two located in each row of light receivers, and then the difference signals are summed up to produce a contrast output signal. At the moment of precise focusing, the light-receivers are located on either side of the film panel the plane conjugated to it). In this case, the output signals from each line of light-receivers must be equalized by G2. A disadvantage of the known device is the low accuracy associated with a limited aperture whose size is due to the applied plane-parallel plate, as well as a small field of view along the vertical line due to the use of narrow lines of light-receivers that exclude focusing on objects whose boundary image is projected along the line of receivers. by increasing the aperture ratio and the field of view of the focusing system. This goal is achieved in that the device for focusing the lens containing the object to be focused c, the sighting device, a mirror mirror, a beam-splitting element installed near the plane adjacent to the focusing plane of the lens, and forming two optical channels, each of which has a multi-element light receiver, as well as a signal processing unit, with comparators, at the output which includes a positioning device for precise focusing, a wrapping optical system is introduced, located in one of the optical channels behind the beam-splitting element, the image plane behind which placed at equal distance from the dividing plane and mated with the focusing plane of the shooting lens, aligned with the object plane of the reversing optical system, in the image plane of which the multi-element light receiver is located, with the corresponding elements of each multi-element light-receiving device connected in pairs to the signal processing unit. In order to reduce the size of the device when using two multi-element light-receivers located on one substrate, the wrapping system is made in the form of a prism block with three reflecting DIM edges, the lenses are mounted on the entrance and exit faces. In the signal processing unit, the elements of multi-element light-receivers are connected in pairs to the inputs of comparators whose outputs are connected to the input of an input unit AND connected to an indicator. In another embodiment of the electric circuit, the outputs of the comparators are connected to the input of an input adder whose output is through an introduced additional comparator connected to the indicator. Figure 1 shows a schematic diagram of a mirror camera with a dp focusing device for a lens; 2 is an optical diagram explaining the principle of operation of the device; FIGS. 3 and 4 show the orientations of the areas of the first and second multi-element light receivers, containing 9 elements each with respect to the images of objects; and 6, the orientations of the areas of the first and second multi-element light receivers, containing 6 elements each, with respect to the images m of objects; Fig. 7 is a structural electrical circuit diagram of a semi-automatic focusing system; Fig. the same, the second embodiment; 9 is an electrical block diagram for determining the absolute differences of signals; The optical scheme of a mirror photo of an apparatus with a focusing device includes a focused lens 1 and a sighting device 2 arranged along the optical axis of the lens 2, made in the central part translucent, an additional mirror 3 translucent beam-splitting part , for example, in the form of a cube 4, which wraps the optical system 5 in the form of two lenses with prisms 6 and 7, a collective .8, light-receivers 9 and 10, diaphragms 11 and 12 in front of the light receiving The rims 9, 10 located in the plane adjoined to the plane of the frame window 13 of the camera. The optical scheme of the sight contains a mirror 2, a collective lens 14, a penta prism 15, an eyepiece 16. An indication device 17 (for example, in the form of an LED) is entered into the field of view of the sight. Multi-element light sensors 9 and 10 are connected to the electronic focusing circuit 18, which controls the display device 17. In order to automatically focus the lens 1, a block 19 is inserted into the camera, which contains an electric motor, an electronic control circuit and a drive connecting the motor to the lens 1. In semi-automatic focusing, the block 19 is missing. The entire focusing device and the sighting system are located in the housing 20, which also contains a photo camera 21, for example, a focal one. The block diagram of the electronic unit 19 contains comparators 24 associated with elements 22 and 23, respectively, of the light-receivers 9 and 10, the outputs of which are connected to the circuit 25 1 (circuit AND or AND-NEL connected to block 26 (circuit AND AND-NOT) connected through a resistance 27 with an indakator 17. In the form of a LED. In another variant of building a structural electronic unit 19, the elements 22 and 23 are connected to circuits 28 connected to an adder 29 whose closure is connected to a two-threshold comparator 30 consisting of resistors 31- 33, operational amplifiers 34 and 35 and intelligent bodies 36, from the output of which the signal is fed to block 26, connected via resistor 27 with LED 17. The device works as follows: When lens 1 is installed on a scale (not shown by HoJ cameras on the distance of the fiso fd), the image has a size of TC in the planes of the installation of the diaphragms P and 12 mated with the plane of the frame window 13 using the reflecting surface of the cube 4; Forces directly on the elements of the multi-element light-receiver 9, in another channel, the reversing optical system 5 gives an image of the intermediate image of the object U in the installation of the multi-element light-receiver 10. When the object is moved from infinity to the near distance d, its size Yd} its image at the same position of the lens 1 will be

at a distance of L from the initial {size of Ua i-iC}). The revising system 5 gives the image of the object WA on an enlarged scale at the distance / lofeopOT of the original V. The guiding optical system 5 gives a linear increase equal to 1 {however it may not be equal to I then the size of the elements of the light detector 10 should be proportionally changed /. At a magnification of 1, the turn-around optical system 5 is set at a distance of 2 f jr from the NPO for the setting of diaphragol 12 (Gd of the front focus of the system, fg back I focus).

When the lens 1 is extended but towards the object У / by the value D of focusing the lens, its image passes in the plane of installation of diaphragms 11 and 12 and, therefore, on the surface of the light-receivers 9 and lOi. The dimensions of the images by 9 and 10 become equal. light-receivers 9 and 0 (d dimensions are not equal to each other. The image of d is larger than image V I. This is obtained due to the use of the reversing system 5 in one of the channels. On this property of inequality of images this principle Focus topics

In this focusing system, the signals of all the elements, for example photodiodes, of the first 9 and second 10 multi-element light receivers are compared in pairs, which allows the system to be focused on objects of arbitrary shape, for example, a grid or other type of objective. If images of an object are obtained in the planes of installation of snapshots 11 and 12, then the illumination of all the corresponding points of planes 11 and 12 are equal, which indicates accurate focusing of lens 1, If lens 1 is not focused on the object, then the dimensions of the images obtained at multi-element light-receivers 9 and 10 are not equal and the illuminances of the corresponding points of the image are also not equal.

Since the device uses a wrapped optical system 5, the image on the multi-element light-receiver 9 is reversed relative to the image on the light-receiver 10. Therefore, the connection circuit of pairs

the light-receivers 9 and 10 should correspond to FIG. 3, where the view of them from the side of the photosensitive surface is shown. The same numerals denote those cells that are compared in pairs, for example, cell 1 on set 4 should be compared with cell 1 on set 5.

Multi-element light-receivers 9 and 10 may, for example, consist of 9 elements and W.-WD, respectively, arranged along horizontal and vertical lines. They may be located differently, for example, at equal distances from the optical axis, the origin of coordinates XY, B In this case, they can contain, for example, 6 elements in each light receiver, C. | -Sb and respectively. An object of arbitrary shape are the elements a, b, c, d, d.

If the image is not focused in the plane of the multi-element light-receiver 9, then on the elements. a part of the image falls (shaded areas from elements a, b, c, d, reduced scale. The elements of the light receiver GO get parts of the image a, b, c, d, d on an enlarged scale. At the same time, the illumination of each of the elements of the pair (,, СЗ -BZIT, D,) are not the same due to the different size of the image on two multi-element light-receivers 9 and 10.

In the position when the lens I is aimed at the subject, the magnitudes of the image elements (a, b, c, d, e) on the C-Cg and D-Dg elements of the light receiving cells 9 and 10 are equalized and their relative position becomes completely identical, which is f moment of exact focusing.

The structural electronic circuit of the block 18 with the indicator 17 for the semi-automatic focusing device can be performed, for example, as follows. The first multi-element light receiver 9 consists of six elements. (Photodetectors 22, a photodiode with an operational amplifier. The second multi-element light receiver 10 consists of the same six elements 23,

The signals from the two corresponding photodetector devices 22 W 23 are fed to the input of one of six comparators 24, the outputs of the comparators 24 are connected to circuit 25 (circuit I; or Cg-Sh.), In the event that all signals are fed to the inputs of comparators 24 coincide (the moment of exact focusing, there will be six identical signals at the inputs of the complexors 24 and the circuit 25 will work by giving a signal to the input of the block 26 (AND or NAND / circuit, which will turn on the indicator 17 through the resistance 27) at the moment of precise focusing, the light comes on T of the indicator 17 in the field of viewpoint of the camera. In another version of the electronic circuit, the photoreceivers 22 and 23 are connected to the circuits 2B, in which the absolute values of the signal difference from the photoreceivers are formed. Then all six differences are added to the adder 29, from which the signal is fed to a two-threshold comparator 30, consisting of a resistor 31–33, an operational amplifier 34 L 35 and a multiplier 36 (i circuit AND or), the signal from output 36 is fed, as in the previous circuit, to block 26 and through resistance p 17 in the form of a LED. A circuit for generating absolute values of the signal difference 28 consisting of resistors, op-amps op amps, op-amp 2, op-amp 3 and diodes d1 and e2. The difference between the two signals transmitted through the resistance RQ is formed by the op-amp,. and the absolute value of the difference is obtained in a circuit consisting of OU2 and OVZ and diodes D1 and D2 and resistors. Circuit 30 is configured so that the signal for the ignition of the LED of the indicator 17 is given when the signal differences from circuit 28 are minimal, i.e. the images on the light receivers 9 and 10 are identical. The use of this B11 focusing system is advisable in single-lens reflex cameras, where interchangeable lenses are used, and it is advisable to automatically focus on the lens (;; the lens is always moved from one source, for example, its distortionlessness, as in diagram No. & the defocusing sign is detected. Locking the movement of the lens must {come out at the moment when the light indicator turns on. Introduction of an optical focusing device to the channel channels a light-borne man n floor system | waggered device allowed in} so% to get there. in the camera interchangeable optical devices practically any light intensity.

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Claims (4)

1. DEVICE FOR FOCUSING A LENS, containing a focusable lens, a sighting device, a reflecting mirror, a beam splitter installed near a plane conjugated with the lens focusing plane, and forming two optical channels, each of which has a multi-element light receiver, and signal processing unit with comparators, at the output of which a device for indicating the exact focus position is turned on, which differs from the fact that, in order to increase the focusing accuracy, a revolution is introduced into it The optical system located in one of the optical channels behind the beam splitter, the image planes behind which are located at an equal distance from the division plane and are conjugated with the focus plane of the shooting lens, combined with the subject plane of the wrapping optical system, in the image plane of which there is a multi-element light detector, the corresponding elements of each multi-element light detector are connected in pairs to the signal processing unit. 2. The device according to claim 1, wherein the, in order to reduce its dimensions, the wrapping system is made in the form of a prism block with three reflective faces, lenses are installed on the input and output faces of which. 3. The device according to π.1, characterized in that in the signal processing unit, the elements of multi-element light receivers are connected in pairs to the inputs of the comparators, the outputs of which are connected to the input of the input block And, the output associated with the indicator. 4. The device according to paragraphs. 1 and 3, characterized in that the outputs of the comparators are connected to the input of the input adder, the output of which through the input of an additional comparator is connected to the indicator. at