DE4230179A1 - DEVICE FOR STEREO PHOTOGRAPHY - Google Patents

Description

The present invention relates to a camera for op table paralax stereo photography where the same Object from different horizontal positions Strip is recorded on the same film negative Groups of vertical striped representations form, the camera intermittently on a Tripod is moved.

According to the known state of the art, the object recorded on different negatives, the camera arranged in different horizontal positions is going to be using a cylindrical lenticular array to get spatial (anaglyph) image, and this Exposures become images outside the camera combined that from different groups vertical striped representations exist. The combined The picture is then made with a membrane from a grid cylindrical lenses, so that the stereo effect of the spatial image can be observed directly. Among the devices that use this method is the US Nimsrol stereo camera known to the has four lenses with which four Nega simultaneously tive can be exposed from the same object. These four negatives can then be in a special Developing device combined into an image the one that consists of four groups of vertical stripes Representations exist that are cylindri with a grid lentils are covered. Despite everything, with the above camera four exposures are made and then a special developing device is required such. In addition, it is very difficult with egg to shoot such a camera, there are many ar training courses are required and the costs are too high.  

The object of the present invention is a stereo camera to create a number of shots that of the same object by using the Camera moved to different horizontal positions can combine directly inside the camera, whereby the representations are combined directly into an image be made up of a variety of vertical stripes consists. In such a stereo camera, a norma film and normal photo and development processes are applied. she is therefore easy to handle, requires little work gears, and the cost is much lower. With a Such a camera can be used largely in stereo photography daily life to be introduced.

The invention is intended to be explained below using an exemplary embodiment, with reference to the associated drawing are explained in more detail in which

Fig. 1 is a front view of the Ste reokamera according to the invention;

Fig. 2 is a plan view of the stereo camera according to the invention when it is in a first position;

Figure 3 is an illustration of the displacement mechanism of the stereo camera of the invention with the portion above the top support plate removed;

Fig. 4 is a plan view of the stereo camera according to the invention with the upper part and including the upper support plate;

Fig. 5 and 6, a plan view and a side view in section of the convergence Steuerungsmechanis are mus;

Figures 7 and 8 show the position of the camera swivel seat when the convergence control block is positioned so that the centerline of the bolt coincides with the centerline of the shaft;

Figures 9 and 10 show the position of the camera swivel seat when the convergence control block is removed from but close to the shaft;

Figures 11 and 12 show the position of the camera swivel seat when the convergence control block is located far from the shaft;

Fig. 13 and 14 are plan views of the closure mechanism and the trigger above or below the support plate when the pin of the drive disc is just entering a groove of the Nu tenrades, the number of grooves being four;

FIGS. 15 and 16 are plan views of the Verschlußspannme mechanism and the shutter button above or below the support plate to show when the bolt of the drive pulley has entered the groove of the Nutenrades and has rotated through 45 ° in the clockwise direction, wherein the number of grooves is four ;

Fig. 17 and 18 are plan views of the closure mechanism and the trigger above or below the support plate when the bolt of the drive disc just leaves the groove of the grooved wheel, the number of grooves being four;

FIGS. 19 and 20 are plan views of the Verschlußspannme mechanism and the shutter button above or below the support plate to show when the bolt of the drive pulley relative to its position shown in FIG. 14, has rotated through 180 ° in the clockwise direction, where the number of grooves is four;

Fig. 21 and 22 a side view in section relation ship, a top view of the Streifenbe wegungsmechanismus show, the carrier is fixed on the camera, which is part of the base;

Fig. 23 is a front view of the stripe movement mechanism arranged in the camera;

Fig. 24 shows a section along the line BB in Fig. 23;

Fig. 25 shows a section along the line AA in Fig. 23;

Fig. 26 is an illustration showing the changes in the convergence angle and the shifting of the stripes when a stereo camera for directly composing four images is arranged at four different horizontal positions;

Fig. 27 shows the relations between the rotation angles of the camera and the drive groove for rotating the camera when the camera is in its first stationary position, as shown in Fig. 26;

Fig. 28 shows the relations between the angles of rotation of the camera and its drive groove for rotation when the camera is in its second stationary position, as shown in Fig. 26;

Fig. 29 shows the relations between the rotation angles of the camera and its drive groove for rotation when the camera is in its third stationary position, as shown in Fig. 26;

Fig. 30 shows the relations between the rotation angles of the camera and its drive groove for rotation when the camera is in its fourth stationary position, as shown in Fig. 26.

The device for stereo photography, with direct Composition of a large number of representations, according to the present invention, contains a Camera and a base for this. In addition to the usual parts, such as lens, aperture, shutter, film transport, counter and so on, is the fiction according camera with a strip element and a mechanism for moving the strip element Mistake. In addition, the locking mechanism nism and the film transport operated separately. The was achieved in that a crank connection with a pin on the rotating ring for the film reel, which on Bottom of the camera was arranged, removed and likewise the spring stop pin, which connects to the crank link formed so that the lock cannot be stretched while the film is being transported is tiert. Instead, instead of the above Spring stop pin a locking bolt the front  lying stereo recording device used to the to operate corresponding locking tensioning elements. On this way the camera shutter can be tightened several times be, although the film transport only for a negative he follows.

The basis for the device according to the invention contains a carrier on which a camera movement mechanism and a convergence control mechanism are to meet the requirements for paralaxe stereo to fulfill photography, a locking mechanism mus, a trigger and a streak motion mecha nism; which still has an engine and a translation contains. All of these mechanisms form one kinetic connection, with the help of a gear ratio, an intermittently movable mechanism and a number of waves between an upper one Carrier plate and a lower carrier plate on the mentioned base are arranged. After the film for exposure has been applied, the kinetic Connect the camera repeatedly, two to eight times, move and stop, including their rotation according to the requirements of the convergence control, and tighten the fastener and move the strips ben (the shutter is only released when the camera stands still). In this way, a variety of grup vertical stripe-shaped representations directly can be combined on the same negative.

It will now be given, with reference to the accompanying drawings, a detailed description of a preferred embodiment. Figs. 1, 3 and 4 show the transmission mechanism of the present apparatus for the stereo photography. On a motor shaft 1 , a pulley 11 is arranged; on a shaft 2 a pulley 13 for reducing the speed and a pinion 14 ; on the shaft 3 a toothed wheel 15 and a pinion 16 ; on the shaft 4 a gear 17 and a drive pulley 18 ; a drive pulley pin 20 is provided on the drive pulley 18 ; on the shaft 5 a grooved wheel 20 and an intermittently rotating gear 21 ; on the shaft 6 a locking tension gear 22 ; on the shaft 7 a gear 23 , a camera movement gear 24 and a pinion 26 ; on the shaft 8 a gear 27 and a pinion 28 ; and a gear 29 on the shaft 9 . The above parts are either tightly attached to the shafts 2 to 9 or fixed with pins. The waves are exactly in corre sponding holes in the upper support plate 31 and the lower support plate 30 so that they can rotate freely between the two plates. The motor 10 is mounted on a motor console 32 and the motor console 32 in turn, together with the lower carrier plate 30 , is arranged on a sliding seat 36 ; the sliding seat 36 is in turn mounted on a slide rail 33 . Furthermore, a rack 25 is hen vorgese, which is fixed by means of two rack support plates 34 , 35 to the slide rail 33 , and the Ka mera movement gear 24 is in engagement with the rack 25 . When the camera movement gear 24 rotates, the sliding seat 36 is caused to move together with the slide rail 33 .

Reference is now made to FIGS. 1 and 2. The camera carrier of the device for stereo photography according to the invention contains the slide rail 33 , the slide seat 36 , which can move along the slide rail, further the rack support plates 34 , 35 , which are fastened to the slide rail, a lower support plate 30 , which on the slide seat is attached, an upper support plate, 31 , and the motor console 32 . The camera housing 39 is arranged on the camera rotating seat 55 , which in turn is attached to the upper support plate 31 .

FIGS. 3 and 4 show a speed-reducing mechanism for the present device including the motor pulley 11 which is attached to the motor shaft 1, a belt 12, the pulley 13 for speed reduction, and the pinion gear 14, both mounted on the shaft 2 , the gear 15 , fixed on the shaft 3 and in engagement with the pinion 14 and the pinion 16 , coaxial with the gear 15th

In this way, the speed of the motor shaft is greatly reduced by the pulleys and gears when it arrives at shaft 3 .

Figs. 2 and 4 show an intermittent movement mechanism of the present invention incorporating the gear 17, mounted on the shaft 4, and hen with the pinion 16 in engagement, the driving pulley 18, coaxial with shipping with the gear 17 and with the pin 19 , which is attached to the grooved wheel 20 , BEFE Stigt on the shaft 5 , the intermittently rotating gear 21 and a cam 53 for locating the strips. If the pin 19 slides in a groove of the grooved wheel 20 , the shaft 5 is also set in motion; when the pin 19 is at a distance from the grooved wheel 20 , the shaft 5 stops rotating. In this way, an intermittent movement of the shaft 5 , the gear 21 and the cam 53 for localizing the strips is realized.

Reference is now made to FIGS. 3 and 4. A camera movement mechanism according to the present invention includes the gear 23 mounted on the shaft 7 and in mesh with the gear 21 , the camera moving gear 24 , coaxial with the gear 23 and the rack 25 attached to the rack support plates 34 , and 35 is attached and is in engagement with the camera movement gear 24 . When the motor shaft 1 rotates clockwise, the camera movement gear 24 also rotates clockwise with the aid of the belt transmission. The camera movement gear 24 in turn sets the rack 25 in motion, which causes the sliding seat 36 to slide to the left along the slide rail 33 . When the motor shaft 1 rotates counterclockwise, the sliding seat 36 slides to the right along the slide rail 33 .

A convergence control mechanism for the present invention is shown in FIGS. 4 through 12. Reference is first made to FIG. 4. For setting the convergence, a translation is provided, which is fixed on the shaft 8 from the gear 27 and engages with the pinion 26 which is arranged on the shaft 7 , the pinion 28 , coaxial with the gear 27 , and Gear 29 , arranged on the shaft 9 and engaged with the pinion 28 , together. FIGS. 5 and 6 further show the con vergence control mechanism of the present dung OF INVENTION. The parts which are arranged above the upper support plate 31 contain a drive groove 63 for camera rotation which is arranged on the shaft 9 , a sliding block 62 which can slide into the groove 63 , the camera rotating seat 55 , with the upper support plate 31 , connected by a camera rotating spindle 58 and a screw 57 , a convergence localization block 59 arranged on the camera rotating seat 55 , a convergence adjusting groove 61 and a bolt 60 which is screwed firmly into the convergence localization block 59 , and further by a threaded hole protrudes into the groove 61 , and is rotatably inserted through another hole in the slide block 62 .

The speed is reduced in such a way by the above-mentioned translation that during each shift of the camera the drive groove 63 only rotates by a relatively small angle (within 15 °) to rotate the camera. In addition, the drive groove 63 rotates clockwise to rotate the camera when the camera moves to the left, and when the camera moves to the right, the drive groove 63 rotates counterclockwise to rotate the camera to meet the convergence control requirements.

FIGS. 7 to 12 show the changes in Drehwin kels and the position of the camera, has when the at triebsnut 63 rotated to camera rotation about different angles, so that the fixed adjustment groove with the convergence 61 connected to convergence localization block 59 on the camera - Rotating seat 55 is brought into different positions.

Fig. 7 shows the state in which the convergence localization block 59 is arranged in such a position that the bolt 60 concentrically coincides with the center line of the shaft 9 . In this position, the angle of rotation of the camera swivel seat is zero. As seen in FIG. 8, in the above position, the centerline of the bore in the slide block 62 (that is, the centerline of the bolt 60 ) is just in the line that the centerline of the shaft 9 and that of the camera spindle 58 connects; the camera rotating seat 55 is therefore not rotated.

Fig. 9 shows the state in which the convergence localization block 59 is arranged in such a position on the camera rotary seat 55 that the center line of the bolt 60 is located at a small distance from the shaft 9 , with the result that the Kame ra swivel seat 55 is rotated through a small angle. With reference to FIG. 10 it can be seen that, through the drive groove 63 for camera rotation, with the aid of the bolt 60 which passes through the bore in the sliding block 62 and is firmly connected to the convergence localization block 59 , the camera - Rotating seat 55 is only rotated around the camera rotating spindle 58 by a relatively small angle.

Fig. 11 shows another state in which the convergence locating block 59 is arranged on the camera rotating seat 55 so that the center line of the bolt 60 is at a large distance from that of the shaft 9 , with the result that the camera swivel seat 55 has been rotated through a relatively large angle. As can be seen in FIG. 12, by controlling the drive groove 63 for camera rotation with the aid of the bolt 60 , which passes through the bore in the sliding block 62 and with which the convergence locating block 59 is firmly connected, the camera Rotating seat 55 rotated through a relatively large angle around the camera rotating spindle 58 .

The settings shown in FIGS . 7 through 12 can meet all of the requirements for convergence control in accordance with the present invention. If an object is to be photographed at infinite distance, the camera is not rotated during the various exposures. If a very close subject is to be captured, the camera is rotated through a large angle for each of the exposures. If an object is to be captured between these two distances, the camera is rotated by a relatively small angle for each exposure. Since the various positions of the convergence localization block 59 are marked in the groove of the camera rotary seat 55 (corresponding to the different distances of the object) on the camera rotary seat 55 , it is possible to set the required position of the convergence localization block 59 to determine according to the distance of the object to be recorded.

The shutter release mechanism and trigger of the present invention are shown in Figs. 13-20.

The shutter tensioning mechanism includes the shutter tensioning gear 22 which is arranged on the shaft 6 , a shutter tensioning cam 37 and a shutter tensioning bolt 38 which is connected to the shutter mechanism of the camera. The shutter tension gear 22 is engaged with the intermittently rotating gear 21 , the number of teeth of which is an integer multiple of that of the shutter tension gear 22 , the integer multiple being equal to the number of grooves in the slot gear 20 .

The trigger of the present invention includes a trigger cam 40 attached to the shaft 4 , a wire trigger 42 , a wire trigger bolt 41, and a wire trigger bracket 43 attached to the upper support plate 31 . The wire release 42, which is attached to said support 43 , is connected at one end to the wire release pin 41 and at the other end to the release button 64 of the camera.

FIGS. 13 and 14 show a state in which the pin 19 enters the drive pulley 18, which has rotated in a clockwise direction, especially in a groove in the grooved wheel 20th At this time, the United clamping cam 37 is at a distance from the locking bolt 38 , so that the bolt 38 is in a relaxed state. At the same time the shutter release cam 40 is at a distance from the cable release bolt 41, so that the Drahtauslö serbolzen 41 also is in a relaxed state.

FIGS. 15 and 16 show another state in which the drive pulley 18 has rotated relative to the Fig. 14 by 45 ° clockwise, and the pin is entered into a groove of Nutenrads 20 19.

Here, the grooved gear 20 was rotated by the pin 19 by 45 ° counterclockwise, and the intermittently rotating gear 21 was also rotated by 45 ° ge counterclockwise, with the result that the locking tension gear 22 by 180 ° has been turned clockwise. The shutter release cam 37 has also rotated clockwise through 180 °, whereupon it presses on the shutter release pin 38 to tension the shutter of the camera. At the same time, the release cam 40 , which is arranged coaxially to the drive disk 18 , has rotated 45 ° clockwise and is now in contact with the wire release pin 41 .

FIGS. 17 and 18 show a third state in which the pin 18 has rotated 19 of the drive disc in the Ver haltnis to Fig. 14 through 90 ° clockwise, and leaves just the groove of the Nutenrads 20th As can be seen, the grooved wheel 20 has rotated 90 ° counterclockwise in relation to FIG. 14. The locking tensioning cam 37 was turned back into its original position in accordance with FIG. 13 and is at a distance from the locking tensioning pin 38 . The locking bolt 38 is again in the tensioned state. The release cam 40, in turn, has also rotated 90 ° clockwise in relation to FIG. 13 and now presses release pin 41 against the wire, but not so strongly that the closure is released.

FIGS. 19 and 20 show a fourth state in which the pin 19 has rotated relative to the Fig. 14 by 180 ° clockwise. At this time, the convex surface of the drive pulley 18 is just in contact with the concave surface of the sprocket 20 . The grooved wheel 20 remains stationary, as does the camera. The release cam 40 , when it rotated from the position in FIG. 17 into that in FIG. 19, pushed the wire release bolt inwards far enough to release the lock.

The strip movement mechanism according to FIG of the present invention. This Mechanism is divided into two parts, namely the part that is arranged on the camera mount and the part that is placed in the camera.

As shown in FIGS. 21 and 22, the part of the stripe movement mechanism which is arranged on the camera carrier contains the stripe localization cam 53 , fixed on the shaft 5 , the camera rotating seat 55 , which by means of the camera rotating spindle 58 and the screw 57 is connected to the upper support plate 31, further comprising the tape printing pin 54, disposed above the camera rotation seat 55, the screw 57 and a spring 56, the bolt-connecting the screw 57 and the pressure 54 and suppressed as the pressure pin 54 that its sharp end remains in contact with an edge of the strip locating cam 53 . In a variant of the present invention, the strip localization cam 53 consists of four convex and four concave curves, the four concave curves being designed so that each forms part of a circle, the center of which coincides with the center of the camera rotating spindle 58 . The function of the concave curves is to leave the strip pressure bolt 54 not shifted when the camera rotating seat 55 rotates; they are therefore called localization curves. If different concave curves on the stripe locating cam 53 have different radii to the center of the spindle 58 , the pressure pin 54 is displaced over different distances.

As seen in Figs. 23-25, the parts of the strip moving mechanism which are arranged in the camera include a film guide 44 for the film section, which is attached to the camera body 39 , a strip plate sliding block 45 arranged in a sliding groove the film guide 44 , a strip plate 46 attached to the slide block 45 , a slide plate 47 arranged in a slide groove of the slide block 45 , an eccentric wheel 48 arranged in a bore in the slide plate 47 , an eccentric wheel rotary lever 50 , a seat 52 for one Threaded tube, arranged on the film guide 44 , a threaded tube 51 , arranged in the seat 52 and a screw 49 , which firmly secures the eccentric wheel 48 and the eccentric wheel rotary lever 50 to the threaded tube. By adjusting the angular position of the eccentric wheel 48 with respect to the rotary lever 50 to which it is fixedly attached, it is possible to set the corresponding displacement range of the strip plate 46 when the rotary lever 50 moves through a certain angle. The film is arranged between two high webs at the top and bottom of the film guide 44 and is pressed by a film pressure plate against two flat webs, which are provided on the film guide 44 a little inside the high webs, the height difference between the high and the flat Webs is slightly less than the thickness of the film, so that the film can be pressed firmly onto the flat webs by the pressure plate and remains stationary when the sliding block 45 moves. On both sides of the slide block 45 , two vertical webs are provided, and the Strei fenplatte 46 is tight in the vertical webs. The vertical ridges are slightly lower than the flat ridges on the film guide 44 (the smaller the gap is, the better), and the strip plate 46 in turn is somewhat flatter than the vertical ridges on the sliding block 45 , so that the sliding block 45 is still can slide freely in the film guide 44 when the film pressure plate presses on the film, while a narrow gap is maintained between the strip plate and the film. The smaller the gap, the clearer the vertical stripes on the film.

The free end of the eccentric wheel rotary lever 50 extends through a base plate of the camera housing 39 and is inserted into a rectangular opening in the strip pressure bolt 54 close to its pointed end, so that the movement of the strip movement mechanism based on the strip movement mechanism is transmitted in the camera can become when the pressure pin moves.

Referring now to FIGS. 30 to reference ge taken 2 and 26.

When the camera is in a first stationary position, its angle of rotation is zero and the optical axis of the lens 65 faces forward. The United closing tensioning cam 37 has already finished tensioning and the strip localization cam 53 is in contact with the strip pressure bolt 54 at point A (as shown in FIG. 2). The convergence localization block 59 is positioned at a location remote from the shaft 9 . L is the distance from the camera to the object. The release cam 40 has rotated so that it presses on the wire release pin 41 , but not so much that the shutter is released. When power is supplied to cause the motor pulley 11 to rotate clockwise, the shaft 4 causes the trip cam 40 to also turn clockwise, thereby pushing the wire trip pin 41 to release the camera shutter. Light passes through the stripe plate 46 so that the film is exposed to produce a first group of latent streak representations. The photography in the first stationary position is now complete.

The motor pulley continues to rotate clockwise, so that the transmission of various mechanisms causes the camera to move a predetermined distance 1 to the left, and the drive groove 63 is rotated to rotate the camera through an angle R, resulting in this that the camera has rotated by an angle β in relation to its first stationary position. The lens 65 is focused on the object and the shutter is clamped by the shutter bolt 38 . The stripe locating cam 53 is rotated 90 ° counterclockwise so that it is in contact with the pressure pin 54 at point B (see Fig. 2). This is a second stationary position, at the same time the strip has pressed pressure bolt 54 onto the eccentric wheel rotary lever 50 , so that the strip plate 46 has been moved by a distance of 1/4 b with respect to its first position (b is the width between two strips of the Strip plate 46 ). This moved the camera to a second stationary position.

In the further course, the motor pulley 11 continues to rotate clockwise and the release cam 40 also continues to rotate clockwise and presses on the pressure pin 41 of the cable release and triggers the camera shutter. Light passes through the strip plate 46 to expose the film, creating a second group of latent vertical striped images. This concludes the photography in the second stationary position.

Next, the motor pulley 11 continues to rotate clockwise so that the camera is moved 1 distance to the left. With respect to the first position, the drive groove 63 have rotated through an angle 2R for cam rotation and the camera has rotated through an angle β 2. The optical axis of the lens 65 is directed towards the object, and the shutter clamping bolt 38 has tightened the shutter again. The stripe locating cam 53 has rotated 90 ° counterclockwise and has come to a third stationary position C. The strip pressure bolt 54 has again pressed on the eccentric wheel rotary lever 50 , as a result of which the strip plate 46 moves by a distance 1/2 b with respect to its first position, and thus comes into its third position. As the motor-driven pulley 11 continues to rotate clockwise, the trigger cam 40 also continues to rotate clockwise to press the wire trigger pushpin 41 and trigger the camera shutter. Light falls through the strip plate 46 and the film is exposed to produce a third group of latent vertical striped images. This concludes the photography in the third stationary position.

The pulley 11 continues to rotate clockwise to move the camera another distance 1 to the left. At the same time, the drive groove 63 has rotated by 3R for camera rotation with respect to its first position, and the camera has rotated by β₃. The optical axis of the lens 65 is directed towards the object, and the shutter clamping bolt 38 has tightened the shutter again. The stripe localization cam 53 has rotated 90 ° counterclockwise and has come to a fourth stationary position D. Likewise, the strip pressure bolt 54 has pressed the eccentric wheel turning lever 50 to move the strip plate 46 by 3/4 b with respect to the first position, thereby moving it to the fourth position by 3/4 b, thereby moving it into the fourth position comes. When the pulley 11 continues to rotate clockwise, the trigger cam 40 also continues to rotate clockwise to press the trigger pin 41 on the wire and to trigger the shutter. Light falls through strip plate 46 and the film is exposed to produce a fourth group of vertical striped representations. In stereo photography, the above procedures are referred to as operations. The idling operations are those during which the motor pulley 11 rotates in the opposite direction. During the idle phase, all moving parts move in the opposite direction. During the idle phase, the trigger cam 40 is kept away from the wire trigger pressure pin 41 to prevent exposure of the film. Subsequent exposure of a plurality of groups of vertical stripe representations can be performed by pressing the film feed lever and applying the energy.

By changing the number of grooves in the grooved wheel 20 and also the drive pulley 18 in order to adapt them to the change, it is possible to create a device for stereo photography for the direct combination of 2 to 8 groups of vertical strip-shaped representations. Of course, corresponding changes have to be made both with regard to the length of the slide rail 33 and the rack 25 , and the number of holding positions, as well as the size of the strip localization cam 53 , the displacement distances of the strip plate 46 and the movements and stops of the camera. Fastened or arranged on / on something in the preceding description always refers to permanently mounted, pin connections, screw, or threaded bolt and nut connections.

For a device according to the present invention can use ordinary films and development processes be used. A series of complicated jobs Steps can be done by just one motor switch is turned on, and a variety of Groups of vertical stripes can be combined directly into the same photo will. It is very much with the present device simple, with a grid of cylindrical lenses to get spatial image, and the cost is very low. The stereo effect of the representations can be can be observed without additional equipment. That is why the present invention determines stereo photography far and wide in people's daily lives bring.

Claims (9)

1. Device for stereo photography with a direct composition of a plurality of representations, consisting of a camera and a base for this camera, which contains a lens, an aperture, a shutter, a film guide, and a counting mechanism, characterized in that it is a Stripe fenplatte and a mechanism for moving the strip plate, as well as a special locking bolt contains to realize the separation between the tensioning of the closure and the film transport; that the base includes a camera mount on which a camera movement mechanism is arranged to meet the requirements for para lax stereo photography, a convergence control mechanism, a shutter tensioning mechanism, a release mechanism, a stripe movement mechanism, a motor and a speed ratio; all of the above mechanisms form a kinetic connection with the aid of a gear transmission, further an intermittently moving mechanism and a number of shafts which are arranged between an upper and a lower support plate, so that the kinetic connection repeatedly moves the camera and can stop to release the shutter two to eight times, and that the camera is simultaneously rotated according to the requirements of the convergence control mechanism when it is moved, and that the shutter is tensioned accordingly and the strips are moved properly . 2. Device for stereo photography according to claim 1, characterized in that the camera carrier contains a slide rail ( 33 ), a sliding seat ( 36 ) which can be moved along the slide rail ( 33 ), rack-supporting plates ( 34 , 35 ), the are attached to the slide rail ( 33 ), a lower support plate ( 30 ), which is attached to the sliding seat ( 36 ), an upper support plate ( 31 ), and a motor console ( 32 ), the camera ( 59 ) on a camera -Rotating seat ( 55 ) is arranged, which is attached to the upper support plate ( 31 ). 3. A device for stereo photography according to claim 1, characterized in that the speed ratio contains a motor pulley ( 11 ) which is fixed on the motor shaft ( 1 ), a belt ( 12 ), a translation pulley ( 13 ), arranged on a shaft ( 2 ), a pinion ( 14 ), arranged coaxially with the transmission pulley ( 13 ), a gear ( 15 ) which engages with the pinion ( 14 ) and is arranged on a shaft ( 3 ) and a pinion ( 16 ) , arranged coaxially with the gear ( 15 ). 4. Device for stereo photography according to claim 1 or 3, characterized in that the intermittently moving mechanism contains a gear ( 17 ) arranged on the shaft ( 4 ) and with the pinion ( 16 ) in engagement, a drive pulley ( 18 ), arranged coaxially with the gear ( 17 ) and provided with a pin ( 19 ), a grooved gear ( 20 ) fixed on the shaft ( 5 ), an intermittently rotating gear ( 21 ) and a stripe lo calization cam ( 53 ); such that the shaft ( 5 ) is rotated when the pin ( 19 ) slides into a groove of the grooved wheel ( 20 ) and is held when the pin is distant from the grooved wheel ( 20 ), so that an intermittent Rende movement of the shaft ( 5 ) of the gear ( 21 ) and the strip localization cam ( 53 ) is realized. 5. Stereo photography apparatus according to claim 4, characterized in that the camera movement mechanism includes a gear ( 23 ) arranged on the shaft ( 7 ) and in engagement with the gear ( 21 ), a camera movement gear ( 24 ), coaxially arranged with the gear ( 23 ) and a rack which is attached to the rack mounting plates ( 34 , 35 ) and engages with the camera motion gear ( 24 ). 6. A device for stereo photography according to claim 5, characterized in that the convergence control mechanism has a convergence control translation which is composed of a gear ( 27 ) which is mounted on a shaft ( 8 ) and with a pinion ( 28 ) is engaged, which is arranged on the shaft ( 7 ); a pinion ( 28 ), coaxially with the gear ( 27 ) angeord net; a gear ( 29 ) arranged on the shaft ( 9 ) and in engagement with the pinion ( 28 ); and further includes a camera rotation driving groove ( 63 ) disposed on the shaft ( 9 ); a slide block ( 62 ) which can slide in the drive groove ( 63 ); a camera rotating seat ( 55 ) connected to the upper support plate ( 31 ) by the camera rotating spindle ( 58 ) and a screw ( 57 ); a convergence location block ( 59 ) disposed on the camera swivel seat ( 55 ); a convergence control groove ( 61 ) and a bolt ( 60 ) which is firmly screwed into the convergence localization block ( 59 ) and passes through a threaded hole in the groove ( 61 ) and is rotatably inserted through another hole in the slide block ( 62 ); wherein the convergence control groove ( 61 ) is able to adjust the position of the convergence locating block ( 59 ) on the camera rotating seat ( 55 ) in order to realize an exact convergence setting. 7. A device for stereo photography according to claim 4, characterized in that the shutter clamping mechanism holds a shutter clamping gear ( 22 ) ent, which is arranged on the shaft ( 6 ); a shutter release cam ( 37 ) and a shutter release bolt ( 38 ) connected to the shutter mechanism of the camera; wherein said shutter charging gear with the intermittently rotating gear (21) (22) in engagement, whose number of teeth is an integer multiple of the Ver circuit spun gear (22) which is equal to the number of grooves in the grooved wheel (20) is. 8. A device for stereo photography according to claim 1 or 7, characterized in that the trigger mechanism contains a trigger cam ( 40 ) which is arranged on the shaft ( 4 ); a wire release ( 42 ); a wire release push pin ( 41 ) and a wire release bracket ( 43 ) attached to the upper support plate ( 31 ); wherein the wire trigger ( 42 ) attached to the wire trigger bracket ( 43 ) is connected at one end to the wire trigger pushpin ( 41 ) and at the other end to the camera release button ( 64 ). 9. A stereo photography apparatus according to claim 4, wherein the moving mechanism for the strip plate is divided into a part which is arranged on the camera support and a second part which is arranged in the camera, characterized in that the part which is arranged on the camera support, a stripe localization cam ( 53 ), which is arranged on the shaft ( 5 ); a camera swivel seat ( 55 ), which is fixed with the aid of a camera rotating spindle ( 58 ) and a screw ( 57 ) on the upper support plate ( 31 ); a strip pressure pin (54) which is arranged on the rotary seat (55), wherein a spring (56) connecting the screw (57) with the pressure pin (54) so acts on the pressure pin (54) that its sharp end with an edge of the strip localization cam ( 53 ) remains in contact; that the strip localization cam ( 53 ) has a number of concave curves, the center point of which coincides with the center of the spindle ( 58 ), and the distances of which can be changed in order to obtain different Bewegungsdi punching the strip pressure bolt ( 54 ); that the part of the strip moving mechanism disposed in the camera includes a film guide ( 44 ) installed in the camera body ( 39 ); a strip plate slide block ( 45 ) arranged in a slide groove in the film guide ( 44 ); a strip plate ( 46 ) attached to the slide block ( 45 ); a slide plate ( 47 ) arranged in a slide groove of the slide block ( 45 ); an eccentric wheel ( 48 ) inserted into a bore in the slide plate ( 47 ); an eccentric wheel rotary lever ( 50 ); a seat ( 52 ) on the film guide; a threaded tube ( 51 ), arranged in a bore in the seat ( 52 ) and a screw ( 49 ) which firmly secures the eccentric wheel ( 48 ) and the wheel rotary lever ( 50 ) to the threaded tube ( 51 ); that the eccentric wheel ( 48 ) in its angular position with respect to the wheel rotation lever ( 50 ) to which it is firmly connected, is adjustable bar, so that it is possible to adjust the corresponding range of movement of the strip plate ( 46 ) when it turns the wheel rotating lever ( 50 ) moves by a certain angle; that the eccentric Raddrehhebel (50) has a free end which projects through the base plate of the camera body (39) and which is inserted in a rectangular opening in the tape printing pins (54) near its sharp end, wherein the pressure bolt (54) on the camera swivel seat ( 55 ) is arranged.