DE591731C - Process for image decomposition and composition in television - Google Patents

Description

Image decomposition and composition methods and devices have become known in many ways. In 'practice, the spiral perforated disc has developed from these best proven, as they are the simplest and cheapest constructive, optical and synchronization options offered. The spiral perforated disks in use today usually consist of 0.1 to

to 0.2 mm thick sheet metal and are spiral-shaped equally spaced holes provided. When the disc in the When the image plane is rotated, each hole moves along an image line, so that the The sum of the picture elements visible through the holes results in the picture itself. With consideration that the holes move on a circular path, it is necessary that their outer and inner edges approximate the curvature of that described by them Have circular path. However, this can be done with the small dimensions of the holes

, hardly achieve, and this is the one difficulty in using the spiral perforated disc. If, as a primitive example, one wants to take the picture format of 3 × 4 cm commonly used today as a basis, the division of this picture into 30 lines requires 3 holes, each ι square mm area, the distance from each other is 4 cm. In this case, a spiral perforated disc with a circumference of around 120 cm, i.e. 38 cm in diameter, is required. This dimension is quite inconvenient, but apart from that, the drive of such a disk also requires quite a lot of energy, and this has the disadvantage that the energy required for synchronization is also relatively large and requires a high degree of amplification. The reduction in the disk dimensions would therefore be necessary in every respect, but the reduction in the dimensions of the holes inevitably goes hand in hand with this. With a disc about 20 cm in diameter, the holes would only have an area of about 0.25 mm², and in this case the curved formation of the outer and inner edges would be completely impossible. The relationships become even more unfavorable if the number of picture elements is increased in order to obtain a finer rasterization of the image. So z. B. for the division of the same image into 48 lines with the same size of the picture elements already a disk of about ι m diameter is required. If one were to make this disc with a diameter of 20 cm, one would end up with holes with an area of ¹ ^ ₅ qmm, which can no longer be made with the required accuracy. It has also already been proposed to manufacture the disk photographically. In this case the pane would have to consist of glass or celluloid and, because of the refraction and assimilation of light, could not be thicker than 0.01 to 0.02 mm. Such a thin disk, however, if it is made of glass, is extremely fragile, while such a celluloid disk is not rigid enough.

To the other important image decomposition or image composition devices to mention, it should be noted briefly that the mirror wheel because of its manufacture required, extraordinarily high

59173i

Precision and its resulting high price, as well as because of the necessary large Driving and synchronizing energy to a good and generally applicable device does not meet the requirements to be set, -during the cathode ray oscillograph requires very complicated electrical auxiliaries and double synchronization and, moreover, for immediate

ίο Transmission of the image of physical objects is not suitable. The electrodynamic oscilloscope works under cheaper ones Conditions, however, has the disadvantage that the image is decomposed according to a meander-shaped line and that it is proportionate complicated optical aids are necessary.

The present invention relates to a method for image decomposition and image composition, in which the above disadvantages are all avoided and with smaller dimensions of the apparatus and less Drive or synchronization energy to achieve a very fine rasterization of the image is. This is achieved according to the invention in that the image by means of a rotating mirror on a fixed Image decomposition device thrown or from a fixed image collation ■ 30 settlement device is removed.

The essence of the invention is shown schematically in Figs. The picture of the object to be sent 1 is thrown through the lens 2 onto the mirror 3, which is with the optical axis of the lens 2 encloses an angle of 45 ° and by means of the motor 4 is set in rotation about the optical axis of the lens 2. The mirror throws the image 1 'of the object 1 on the jacket surrounding it, with. spirally arranged Drum 6 provided with holes 5. When the mirror 3 rotates, the image 1 'is on guided along the jacket of the drum 6 and disassembled through the holes 5. Are now outside the drum 6 in the manner shown in Fig. 3 semicircular photocells 7 and 8 are provided, so these exposed by the individual picture elements and transform the light impulses into familiar ones Way in current pulses.

Of course, the operation of the device can also be reversed if instead of the photocells 7 and 8 in the same device glow lamps of the same shape are provided. In this case, those formed by the holes 5 become individual Image elements through the rotating mirror 3 one after the other through the one acting as an objective Lens 2 thrown and put together to form an image.

The method according to the invention has various extremely great advantages. First needs the actual image decomposition or Image composing device, in the above example the perforated spiral drum 6, not to be actuated, but it stands still, and only the light one is moved Mirror 3 with very little air resistance. In addition, the mirror can also be made in a simple way Way be arranged in an air-diluted space 7 ", as is also the case for spiral perforated disks has already been proposed, in which, however, considerable difficulties because of the large dimensions of the disc appear. The energy required to drive the device is therefore extraordinary low, and accordingly the energy required for synchronization will only be very small. The device is completely symmetrical, and the recorded or reproduced image suffers no distortion, it is completely square.

Another extremely big advantage is that of the fixed arrangement the spiral perforated drum given possibility of producing the same with very small Dimensions, which will be discussed in more detail below. .

If both the image decomposition and the image composition in the inventive This is done in a manner that does not require any additional aids other than those indicated above, and the same apparatus can can be used for both purposes. If, on the other hand, the image is broken down according to one of the other known principles and should the apparatus according to the invention can only be used for image composition, ie as a receiving device, care must be taken that the rotating Mirror caused movement of the image around its own axis is compensated. This rotation occurs in any case, but then, if the image is broken down in this way, it is not disturbing, because in this case the rotating mirrors in the sending and receiving apparatus caused rotations of the images cancel each other out. In the other case, the rotation of the image around its own axis can simply be balanced out by the fact that the rays of light on their way from the mirror to the lens in the opposite sense to the optical Axis of the lens can be rotated.

This can for example, as shown in Fig. 4, by means of a between the mirror and the lens switched on, also rotatable, triangular prism 9 causes that is the effect of moving in the opposite sense to the rotation of the mirror 3 rotated mirror. Instead of the-

591? 3i

This prism can of course also be a mirror or lens system, as well as the mirror 3 can also be replaced by prisms, lenses, etc.

In the arrangement according to the invention, the holes do not have to be the size of the picture elements correspond, since the image is enlarged or reduced as desired by the lens 2 can be. It is therefore possible to make very large holes, for example 1 square cm To provide the surface, only need to have their edges in the axial direction of the drum around the Parts of the picture elements, for example, are offset by ι mm. So that's how you are able to increase the image brightness extraordinarily, because the brightness increases according to the increase in the hole size, Thus, for holes with an area of ι sqcm, it is 100 times as large as for holes with an area of 1 sqmm.

From the fact that the actual image decomposition or image composition device is standing and only the image itself moves on it, there is, as already indicated, the possibility of an extraordinary reduction in the dimensions of the apparatus, since one no longer takes place in the manufacture of the perforated spiral drum must pay attention to the easy mobility of the same. One can therefore give the drum a greater weight and thereby achieve advantages with regard to the possible accuracy of the holes. If, for example, a drum is to be produced with holes 0.01 square mm in size, steel rings 10 0.1 mm thick are advantageously used for this purpose (FIGS. 5 and 6), which are provided with a 0.1 mm wide slot 11. To produce a drum with 48 holes, 48 such rings are placed next to one another (Fig. 7) and the slots are changed by 7 ¹ J ₂ ⁰ by means of the nose 12. If these rings are now enclosed between the end rings 13 and pressed together by means of the screw bolts 14, a spiral perforated drum is obtained with 48 precisely square holes, each 0.01 sq mm in area, the drum diameter at 4800 picture elements being only 15 cm. Of course, instead of 0.1 mm thick rings, one could also use 0.01 mm thick rings and thereby obtain hole sizes of 0.001 sq and the holes are delimited by the edges of the slot so that they are precisely delimited by the edges of the adjacent rings. In addition, the holes can be designed in such a way that no diffraction phenomena can occur by the

Slot 11 is punched gradually widening outwards, so that the holes themselves have practically no wall thickness at all. The composition of the drum can thereby be facilitated that the rings are pushed onto the stand, the appropriate is made of glass so that you can insert it into the inside of the stand with the help of a Light source can precisely adjust the holes.

This type of production of the drum has the further advantage that the drum can be provided with a different hole spacing at any time by only adding a corresponding number of rings in order to obtain a drum with more or fewer holes. If you do not want to take the trouble of any-time adjustment of the hole pattern, it may be the drum from the outset with several common hole pitches provided, for example, make up the drum 78 rings, \ ^r on which the first 30 for 30zeilige images and the remaining 48 should be used for 48-line images. Production then takes place by simply shifting the drum in the axial direction. The drum can also be arranged to be displaceable in the circumferential direction in order to be able to carry out any phase corrections conveniently.

The other possibility for the production of the perforated spiral drum is shown in Fig. 8. In the jacket of the drum 15 there are fine slots running parallel to the axis 16 is etched, and another drum 17 is pushed onto this drum, with the an etched spiral 18 is provided. Both etchings together result in a spiral shape arranged holes that are not square, but complement each other.

In the device according to Fig. 9, a normal spiral perforated disk is used instead of the drum

20 used, on the holes of the rotating mirror 3 on a stationary conical mirror 19 thrown image is projected. In this case, too, can obtained an extremely small dimension for the apparatus, as for the fixed one Disk 20 is easily a thin one with holes made by photographic means

21 provided glass pane can be used. ■

Claims (13)

Patent claims: i. Method for image decomposition and composition in television, thereby characterized in that the image by means of a rotating mirror on a fixed Image decomposition device thrown or from a fixed image composer is removed. 2. The method according to claim i, characterized in that the disassembly rotation caused by the rotating mirror of pictures or pictures dismantled in some other way of the image about its own axis by rotating prisms, mirrors or the like. Balanced will. 3. Device for image decomposition and composition, characterized by a fixed disassembling device of known type and an image to be disassembled on top of it project the image to be composed of this decreasing rotating mirror. 4. Device according to claim 3, characterized in that the image decomposition or assembly device consists in a spiral drum and the rotating mirror is arranged inside the drum so that it image to be sent on the drum shell or the image to be received from Drum shell outwards, throws. 5. Device according to claim 3, characterized in that the rotating Mirror is arranged inside a fixed conical mirror, in front of which there is also a fixed Spiral perforated disc is located. 6. Device according to claim 3, characterized in that the perforated spiral drum is surrounded by a circular photocell or a similar glow lamp. 7. Device according to claim 3, characterized in that by way of Light rays from the object to the rotating mirror or from the rotating mirror to the lens are also rotating three-sided prism is arranged. 8. Device according to claim 3, characterized in that the rotating Mirror sits on the axis of a phonic wheel and is set in rotation by this ■. 9. Device according to claim 3, characterized in that the spiral drum is rotatably arranged for the purpose of correcting the phase shift. 10. Device according to claim 3, characterized in that the perforated spiral drum provided with several hole systems with different numbers of holes and arranged to be movable in the axial direction is. 11. Device according to claim 3, characterized in that the perforated spiral drum is composed of rings slotted at one point, the width of the slot of the rings corresponding to the width of the hole. 12. The device according to claim 3, characterized in that the slot of the Rings is wedge-shaped. 13. The device according to claim 3, characterized in that the holes of the Perforated spiral drums are larger than the picture elements and with their corresponding Edges offset by the width of the picture elements in the direction of the drum axis in the drum wall are arranged. 1 sheet of drawings