DE437519C - Device for remote transmission of images, especially for television - Google Patents

Description

The remote transmission of pictures, both picture telegraphy and that Television, as is well known, is based on the fact that the image to be transmitted (optical object) into the smallest possible parts, divided into so-called picture elements, on one of their electrical ones Properties of the lighting correspondingly changing cell is projected, namely in such a way that the individual picture elements impinge on the cell one after the other and this one each influence differently according to their light intensity. This becomes the one flowing through the cell electric current changes, and that corresponds to each picture element certain current pulse.

These current pulses are now transmitted to the receiving station and at a distance there used to influence the strength of a light beam, which is on a collecting surface illuminated a point. This point is moved on the collecting surface in such a way that that the sequence of the illuminated points is exactly the sequence of the on corresponds to the donor station impinging picture elements on the cell. It arise like this Points illuminated one after the other on the collecting surface, their position and illumination that of the successive picture elements of the donor station and thus together reproduce the picture to be transmitted.

In those cases where the images to be transferred are transparent or translucent Bhotographies or the like, the division into picture elements can be as slow as you like.

and any light source of any intensity can be used to illuminate the image. This makes the remote transmission task much easier, and it is facilities for this purpose are already known which give acceptable results.

The matter is quite different and much more difficult, however, if of the

ίο remote transmission of virtual images, d. H. from the So-called television is in question, in which the images to be transmitted are not are fixed, but z. B. formed by lenses in a camera obscura.

No arbitrary light intensity is available for these images, and neither is the Transmission time of the image is very short. The splitting of the image to be transmitted with the donor and also the stringing together of the pixels at the receiver must be at the longest within one eighth of a second. A dem arises every eighth of a second Original corresponding image, which, as with the! Cinematograph, is consecutive results in a uniform continuous picture.

Should z. If, for example, a 5X5 cm image is transmitted and if a subdivision of the same into elements of 1 mm ² , thus a rather coarse subdivision, is assumed, then 2,500 picture elements have to arise in a tenth of a second and therefore 25,000 picture elements in one second. In addition, the subdivision into picture elements at the transmitter must be done synchronously with the reproduction of the points at the receiver, otherwise a true picture cannot be created.

This large number of picture elements or the high speed with which they move also causes an extremely great sensitivity and almost indolence of the Cell, since this has the task of changing the current or current corresponding to each picture element. To transmit impulses from the transmitter to the receiver.

The presence of such cells is assumed in the present invention; the Invention itself relates to those measures which involve dividing the image into Elements at the giver and the correct playback of these elements at the recipient in the enable the sense described above.

Several measures for solving this problem have already been proposed been, however, to no avail because of the large number and speed of movement of the picture elements could not take into account.

In carrying out the division of the image into elements and also in the Playback, d. H. when composing the picture elements, in the present invention 1 uses a system of two mirrors moved at an angle to each other, one of which moves faster than that other. Such mirrors have already been proposed such. B. on the television from Szczepanik. This mirror makes the surface zigzag in Line elements decomposed, and this decomposition is the more extensive, the larger the There is a difference in movement between the two mirrors. With the mentioned known Devices is not sufficient due to the mechanical inertia of the individual components Great speed of movement achievable to even the smallest required Number of picture elements per second.

According to the invention, one, namely the faster moving mirror, is a mirror oscilloscope.

The advantage of using the oscilloscope for disassembly over others relatively very wear devices results from the great possibility of oscillation of the oscilloscope. Another advantage ordered in the small space requirement of the Oscillographs and in the fact that to move the same only an extremely small amount of energy is necessary. Finally, as can be seen from the following, it is extremely important It is of great importance that the synchronization of the analog devices, transmitters and receivers are arranged Oscillographs can be done most accurately and with ease.

A proposal has already been made regarding the composition of the picture elements at the receiving point the mirror effecting the assembly as a mirror of Train oscilloscopes, but only for the purpose of synchronizing them Secure the mirror with the mirrors for the image decomposition at the broadcasting station. That was thereby causing the movement of the mirrors for image dissection to manufacture is used by current pulses, which are then sent through special lines to the oscilloscope at the receiving station be guided. Apart from the need for special line cables for every oscilloscope, and also for the one influenced by the selenium cell Electricity a special line is necessary, this facility is practically useless makes, the purpose on which the invention is based is not pursued here either. As already mentioned, this purpose is to make the mirror move faster to give extremely large and almost inertia-free vibrations. The invention achieves this purpose

achieved in that both on the encoder point for the image decomposition and on the Receiving point for the image composition of the faster moving mirror than mirror ever a mutually independent oscilloscope and designed to operate a each oscilloscope has a special one on both the receiving and the transmitter station interrupted or alternating current

ίο is used with the same number of vibrations. The invention is explained in detail with reference to the accompanying drawing, on which an exemplary embodiment of the subject matter of the invention is shown schematically, namely shows Abib. 1 the donor station and Fig. 2 the receiving station.

The image to be transmitted, any object or part of a terrain is thrown through the objective or lens system 1 on a mirror 2, which by a preferably upright axis swings back and forth. That reflected back through this mirror With every oscillation of the mirror, the image sweeps over a preferably adjustable one Light gap 3 away, so that in each position of the mirror 2 a different strip of the image passes through the gap 3. These strips are now on the mirror 4 an oscilloscope 5 through the intermediary of a lens, expediently a cylindrical lens 6 thrown whose focal point is conveniently in the mirror of the oscilloscope. The mirror of the oscilloscope throws the image on a selenium cell 7, which in the long-distance line 8 of a corresponding power source 9 is switched on directly or indirectly. The pipeline can also be wireless, in which case the selenium cell is connected to the system in the same way as the wireless one Telephony the microphone. The selenium cell influences the amplitudes of the vibrations here.

The oscilloscope becomes correspondingly larger, but more unchangeable, from a current Frequency operated, in such a way that the mirror 4 of the oscilloscope by one below an angle, expediently arranged at a right angle to the axis of the mirror 2 Axis is moving. As a result, the successive, through the light gap continuous strip of images thrown onto the selenium cell in such a way that only one small part, d. H. a picture element that meets the selenium cell. The application of a gap of light between the oscilloscope and selenium cell perpendicular to the light gap 3 is not necessary, if the selenium cell is sufficiently small. Should the image to be transmitted now be in a tenth of a second are broken down into picture elements, the mirror 2 must be ten per second make half or five whole oscillations, the width of the on the oscilloscope mirror 4 thrown image strip is determined by the width of the light gap. Of the Driving the mirror 2 will be described later.

The oscillation number of the oscilloscope is determined by the permissible, desired fineness of the division of the image. So z. For example, in the example already given, where an image of 5X5 cm surface is to be transmitted and the light gap is ¹ ^ mm wide, the oscilloscope has to perform 500 oscillations per second, which is a very low speed for the oscilloscope.

Each picture element that hits the selenium cell changes its light intensity accordingly the resistance of the selenium cell 7, which in the circuit 8 of the power source 9 directly or, as already mentioned, indirectly, e.g. B. by switched on the appropriate Relay, changes are caused.

These changes in current are transferred to the receiver, where they can be influenced of a beam of light used. Measures serving this purpose, so-called light relays, are on and already known for itself.

In Fig. 2 a particularly sensitive new device is indicated for this purpose, the but does not form the subject of the present invention. This new device exists from a mirror oscilloscope 10, on the mirror of an unchangeable light source 11 coming light streak through a gap 12 is thrown, by means of a lens 13, in the focal point of which the oscilloscope mirror lies. The oscilloscope is connected to the long-distance line and is therefore actuated by the impulses generated by the Selenium cell are caused by the donor.

The light beam is then passed through a slot 16 of a diaphragm 15, in such a way that depending on the position or oscillation of the oscilloscope mirror more or less light passes through the slot. The oscillation of the oscilloscope mirror depends on the lighting the selenium cell at the donor, d. H. on the light intensity of the individual picture elements, and therefore the light intensity of the beam passing through the gap 16 is always proportional the light intensity of the incident on the selenium cell at the donor at the same time .Picture element. The sensitivity of the oscilloscope used here must of course take into account the small changes in current.

It is now the task of the receiver to point these different illuminations point by point or in strips in the same sense as the

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Division of the image at the donor took place to unite to form a surface or an image. For this purpose, the receiver has exactly the same device as the transmitter for dismantling.

The light beam 14 passes through the gap 16 to the mirror 17 of an oscilloscope 18, which is operated completely synchronously with the oscilloscope 5 at the encoder. The beam 14 is then on a mirror 19 and from this to a screen, a matt plate or a light-sensitive Thrown plate 20. The mirror 19 swings. synchronous with the mirror 2, that is, they are Mirrors 17, 19 at the receiver are completely adjusted to each other with regard to the axis of oscillation, like mirrors 2, 4 on the encoder. It is therefore readily apparent that the correct work of the described components the picture elements according to their Appear one after the other and proportional to their light intensity on the screen 20 and, if the process takes place in a sufficiently short time, in the human eye a uniform, give continuous picture.

As can already be seen from what has been said, this is the correct mode of operation of the device with sufficient sensitivity and inertia of the selenium cell 7 from synchronous walking the splitting mirror 2, 4 at the donor with the mirrors 18, 19 at the recipient addicted.

In order to ensure that the components mentioned run synchronously, the illustrated embodiment of the mirror 2 operated by a phonic wheel.

As is known, this consists of an expediently slightly upright wave rotatable drum 21 made of non-magnetic '40 shem material, on the circumference of each other at the same distance, along each generating line, slats made of soft iron are attached are. Near the circumference of the drum there is an electromagnet, which is operated by alternating current or by interrupted Direct current is excited. If the drum is now made to rotate, e.g. B. by means of of a finger is set in motion, as soon as the number of revolutions of the drum is so is large that such a number of lamellae passes in front of the electromagnet that the Corresponds to the frequency of the excitation current, the drum comes into phase and is with this number of revolutions is rotated by the electromagnet. To always have a constant frequency of the excitation current To achieve, a direct current source 26 is expediently used, the current through a tuning fork breaker 22 will interrupt.

As is known, the number of revolutions of the phonic wheel 21 is due to the action of the Tuning fork22 completely unchangeable; the mirror 2 at the encoder and the mirror 19 at the receiver are kept vibrating in a very similar way by means of a crank and connecting rod 23. Because the tuning forks 22 of the transmitter and receiver are perfectly matched, is also the number of revolutions of the phonic wheel 21 at the encoder with that of the phonic wheel at the receiver exactly the same, so that mirrors 2 and 19 - one at the same time Assuming the beginning of the movement - run completely synchronously. The number of vibrations the mirror is relatively small, about 8 to 10 vibrations per second; therefore the "phonic wheel" rotates between 240 and 300 times in one minute close.

Of course, other mirrors 2 and 19 can also be operated synchronously running devices are used. However, the application of phonic wheels has. - as from what is stated below emerges - also have particular advantages for operating the oscilloscope. Various devices can be used to operate the oscilloscope. It can e.g. B. be used for this purpose a direct current source in the circuit a tuning fork breaker is switched on, the tuning forks at the receiver and the giver are perfectly matched. The direct current interrupted by the tuning forks is now inserted into the oscilloscope so that the current pulses pass the oscilloscope vibrate.

In order to operate the oscilloscope not with direct current, but with alternating current, can e.g. B. the interrupted direct current in the primary winding of an inductor whose secondary winding is connected to the oscilloscope.

Any other alternating current can be used to operate the oscilloscope the oscilloscope must be aperiodic.

The use of phonic wheels has the advantage that the actuation current of the oscilloscope can be generated by the phonic wheels. There is therefore no need for a special tuning fork to interrupt the current and there is also a _lig dependency, which significantly facilitates the synchronization of the transmitter and receiver.

In the embodiment shown, the phonic wheel rotates a _circuit breaker 24 which is provided with a corresponding number of sectors and is only indicated in the drawing, on which the brush is rotated

25 loops. This circuit breaker is ' on the one hand to the one and on the other hand by means of the brush 25 to the other pole of the; connected to the oscilloscope actuating direct current source 26, which current source can also be used at the same time to actuate the phonic wheel. As a result, current pulses are sent to the oscilloscope> which actuate the same, with a dependency or a forced coupling being created between the movement of the oscilloscope mirror and the slowly moving mirror.

Another embodiment for loading |

operation of the oscilloscope 5 or 18 would be! given by the fact that in addition to the phonic | Wheel induction coils are arranged in which the remanent magnetism of the soft iron sectors of the phonic wheel is Sufficiently strong current or current impulses! induced to operate the oscilloscope. Of course, not only the sectors of the phonic Wheel, but also special per-;

manent magnets used and either!

rotated this or the induction coils!

will. :

It can happen that between ^:

are provided by the phonic wheel on described '■ type for the oscilloscope induced currents even with perfect synchronous passage of the phonic wheels when transmitter and receiver phase shifts, according to which the mirror of the oscilloscope 5 | and 18 assume the same time points in different positions I, so that the pixels formed at the receiver _those: not cover the encoder, thereby obtaining a false image.

4G In order to remedy these evils , the arrangement is made in such a way that the phase angle between the oscilloscope and the phonic! Rade can be regulated. i

This is done simply by; that the induction coils to the soft iron \ segmental or special magnets in the ^! Circles are adjustable. This can be done in many ways.

Claims (8)

Claims: | ι. Device for remote transmission of images, especially for television which is used to break down the image to be transmitted into image elements on the encoder parts and two for assembling the picture elements at the receiving point mirrors oscillating at different speeds are arranged at an appropriate angle, thereby marked that both on the donor station and on the receiving station of the faster moving mirror designed as a mirror of an oscilloscope and for moving both mirrors both on the receiving and on the transmitter point each a locally generated interrupted or Alternating current of the same frequency is applied. 2. Device according to claim 1, characterized in that between the slower moving mirror · (2) and the oscilloscope mirror (4) a light gap (3) is switched on, so that through the same only a strip of the image reflected by the slower moving mirror and expediently through a lens (6), the focus of which is on the oscilloscope mirror, hits the latter, from which it then arrives at the selenium cell (7). 3. Device according to claim 1, characterized by the application of a AC powered aperiodic oscilloscope. 4. Device according to claim 1, characterized in that for production of the current operating the movement device by means of a tuning fork breaker generated interrupted current is applied. 5. Device according to claim 1 to 4, characterized by the application a phonic wheel to move the slower moving mirror. 6. Device according to claim 1, 2, 3 and 5, characterized in that the phonic wheel affects a circuit breaker, which is used to manufacture the Power surges for the oscilloscope switched into the direct current circuit of the same is. 7. Device "according to claim 1, 2 and 3, characterized in that the phonic wheel is designed as a rotor of a power generator for the oscilloscope. 8. Device according to claim 7, characterized in that the primary magnets the power generator to the secondary magnet of the same for the purpose of phase change arranged adjustable in a circle are. For this purpose ι sheet of drawings.