DE661263C - Process for converting an image projected onto a photocathode with all of its brightness values into a mosaic of electrostatic charges and scanning by means of cathode rays - Google Patents

Description

The invention relates to a method for television.

Cathode ray tubes have already been proposed for television transmission equipment, one consisting of a large number of individual, uniformly light-sensitive cells Own cathode. Such cathodes are difficult to manufacture.

According to the present invention, an image of the object to be transmitted is created on Transmitter thrown onto a single contiguous light-sensitive cathode, and the electrons emanating from the latter cause a

> 5 standing anode the storage of electrostatic Charges. The cells are evenly distributed over the anode surface with small distances from one another. This anode is scanned by the cathode ray, causing a continuous neutralization of the electrostatic charges is caused. The charges of the individual cells control the Influence of the probe beam on a circle in the transmitter.

Such an arrangement has all the advantages of a storing scanning device, but, in contrast to previously proposed devices of this type, does not need it an electrode composed of a large number of small individual photocells, whose Individual cells must have the same sensitivity to one another. The problem of photoactivation rather, a large number of elements are bypassed. Occurs at the earlier proposed facilities also has the disadvantage that the memory effect and the image quality deteriorates significantly was caused by the poor insulation between the individual photo elements due to the presence of photoelectric effective materials between these elements.

According to the further invention, an undistorted electrical image is obtained from the photoelectrons emanating from the cathode .developed and the electrical image through a cathode ray is scanned to a circle in a suitable transmitter influence.

The invention is shown in the drawing in nine figures.

Fig. Ι and 2 show on an enlarged scale Parts of a transmission device with the associated circuits.

Fig. 3 and 4 are characteristic curves.

Fig. 5 is a section along 5-5 of Fig. 2.

Fig. 6 is a section along 6-6 of Fig. 5 on a larger scale.

Fig. 7 shows part of a view according to Fig. 5 on a larger scale.

Fig. 8 is a section along 8-8 of Fig. 7.

Fig. 9 is one of Fig. 1 corresponding to ^ Representation of a modified version ^ - f'orm.

In the cathode ray tube 10 of FIG. 1, a coherent light-sensitive surface 11 connected as a cathode is arranged. The image to be transferred is thrown onto this at the same time with all of its brightness values, and the photoelectrically effective surface is thereby excited to emit electrons in accordance with the image brightnesses. Two electrode plates 12 and 13 are arranged parallel to this photocathode ii. In these openings are provided, are inserted in the insulating bushings 14, which is provided for recording with heads _t sixteenth Metal elements 15 are used. Opposite the heads 16 there is a further shield electrode 17, for example in the form of a fine-meshed wire network.

The number and arrangement of the elements 15 corresponds to the number of pixels to be transmitted.

For example, for sending an image of about 32 cm ² , 6400 such elements 15 were used, which were evenly distributed over the area in 80 parallel lines. The cathode ray tube 10 contains an electron generating system 18 which throws the cathode ray onto the elements 15 and an electrode 13 within which these elements are arranged. This beam scans the image area, for example, 12 to 20 times per second. The deflection elements 19, 21 (FIG. 2), which are connected to the associated generators 20 and 22, serve to generate the scanning movement.

The electrode 12 is positive Side and the cathode 11 connected to the negative side of a battery 23 so that between the cathode 11 and the opposite surface of the electrode 12 electrostatic field. The distance between the two electrodes is proportionate small; it is about 3 mm. It is achieved in that the electrostatic Lines of force run parallel to one another and perpendicular to the electrodes 11 - and 12 stand.

The electrode 13 is at one end

24 of a resistor 25, the other end of which is connected to the positive terminal of 23 is connected. The negative terminal of 23 is grounded at 26.

The electrode 17 is connected by a connection via line 27 to the positive side of battery 23 on a fixed positive Tension held. In order to increase this voltage, the Line 27 also has a battery 28 switched on.

The amplifier '; $$! ■ ' is connected to these parts just described by lines 29 and 30, the output lines 32!, J ¹ OMd 33 of which lead to the transmitter.

The image 35 of a. Object 36 (see. Fig. 2) is through the lens 37 on the photosensitive surface of the cathode 11 thrown. ·

The operation of the device is as follows: Each of the electrodes 12 and 13 arranged elements 15 forms a Capacitor that is continuously produced by the electron emission emanating from the photocathode 11 is loaded (indicated by the arrows 39). All emitted from the cathode Electrons! Reach the opposite face of the compound Anode. Both the electrons emitted by the parts 42 and those emitted by the parts 40 the photosensitive surface go under the influence of the electrostatic field through the openings of the cathode 11 to the anode by making the parallel electrostatic Follow lines of force between the opposite faces of 11 and 12, as indicated by the arrows 39 and 43, respectively. The ones that strike metal bodies 12 Electrons are discharged through battery 23 and ground 26 to earth. By the electrons that hit the parts 15 become these according to the treatment the opposite points 40 on the photocathode 11 are charged.

The charge curve of such a capacitor is shown in Fig. 3, in which E _{s represents} the saturation charge and E _ma x the maximum charge corresponding to the greatest image brightness. The charge on the capacitor is therefore always limited to the straight part of the charge characteristic between the limit values zero and E _max . How this is achieved will be explained in more detail.

For the sake of simplicity, the influence of the electron beam 44 is shown at a given moment of impingement on one of the locations 38 of the assembled anode 12, 13 is considered.

The electrons of the beam 44 reach the electrode 17 at a speed which corresponds to the voltage difference between this electrode and the cathode 46. A Part of these electrons strike the screen 17 and are absorbed by it to go to earth via batteries 28 and 23 and earth 26. Those electrons which pass through the openings of the screen 71, meet the with directly the bracket 38 designated area of

composite anode. Some of these electrons hit the head 16 of the Element 15, another on the immediately adjacent surface parts of the Electrode 13, as indicated by arrow 44 ″.

If all elements 15 have the same potential have the same number of electrons hits for each deflecting position of the beam 44 in question on each of these surface parts of the electrode 13. So if on the photosensitive Surface of the cathode 11 is no picture, or when the lighting this surface is uniform, causes the electrons of the beam 44, which come into contact with the surface of 13, as indicated by the arrows 44 ", the flowing of a direct current of constant voltage through the resistor 25 and from there via the battery 23 and Earth to cathode 46. The magnitude of this direct current is determined by the constancy of the number of electrons in each Immediate of the sampling period on the electrode 13 to hit.

However, if any of the elements 15 is charged or its charge is changed from its initial value due to the projecting of an image on the cathode 11 and the consequent change in the light intensity on the various points 40, it changes under the influence of the charge E on the associated element 15 is the number of electrons which reach a certain point on the electrode 13. This change in the number of electrons which reach a certain area of the electrode 13 is inversely proportional to the value of the charge E on the associated element 15 on which the beam 44 is directed at that moment, and is therefore inversely proportional to the light intensity on the neighboring and corresponding point 40 of image 35. A change in the number of electrons that reach the scanned point of the electrode 13 at any given moment causes a change or modulation of the initial DC voltage across the resistor 25. The voltage changes according to this change in the voltage drop across the resistor at the grid 47 of the amplifier 31, the output of which is connected to the transmitter 34 via the lines 32, 33.

The effect just described is due to a negative field that arises at the head 16 of each element 15 and the strength of which is determined by the charge E and changes with it. This field has a retarding effect on the whole number of electrons which pass through the screen 17. If the charge E is relatively small, this retarding effect is also small and the number of electrons hitting 13 is correspondingly large. Conversely, when the charge E is large, the retarding influence is also large and the number of the incident electrons is small.

Those electrons of the beam 44 which strike the head 16 cause a secondary electron emission which is picked up by the screen 17, as indicated by the arrows 49, as a result of which the charge E is discharged within the time td . The electrons of the secondary emission, which are thus drawn towards the screen 17, go to earth via the batteries 28 and 23.

The capacitor charge E controls the influence of the beam 44 with respect to the electrode 13 'by means of the above-mentioned effect and thereby modulates the voltage of the grid 47 via the capacitor 48, and this change is inversely proportional to the size E of the charge.

It should be noted that each of the capacitors, the one-sided of which is the elements 15, is continuously charged as a result of the continuous emission of electrons from the photosensitive surface of 11, the accumulation of charge taking place during the full scanning period of the beam 44. This period is, for example, of the order of magnitude of ¹ Z ₁₂ to ¹ Z ₂ O sec. The time that is required for each element 15 to accumulate the charge f it corresponds to corresponds to the time that elapses between successive contacts of this element with the cathode ray. It is expedient to ensure that, although each element 15 is continuously charged in the manner described, the charging time te is never so long as to cause a greater charge storage than E _max for the brightest image area. The curve in Fig. 4 is intended to reflect the condition where td is approximately ¹ Z ₁₂ of te .

As can be seen in Figs. 5 and 6, the electrode plates 12 and 13 can their edges are clamped between rings 50 made of insulating material, which are lugs Place 51 in the wall of the tube 10. An insulating ring is located between the plates 12 and 13 52. The rings are held together by screws 53. "

In a modified embodiment, instead of the cathode 11, a put light-sensitive semi-transparent layer, which is on one side 64 (Fig. 2) of tube 10 is at the larger end of the tube. In this case it will Picture 35, which is thrown on this layer,

cause electron emission according to arrows 39, 41 and 43.

The storage electrode 12, 13, 15 can be constructed in any way; What is important is that it picks up the electrical image developed at the cathode and that this image is projected from there in the direction of arrows 41 and 39. For example, in the construction according to FIGS. 7 and 8, the anode consists of two parts I2 ^a and iy, each part of which consists of several strips 54 made of nickel or the like. consists. These bands are bent in a zigzag shape and soldered to one another at points 55. Insulating bushings 14 ° are inserted into the openings 56 formed in this way and are used to accommodate the elements 15 °. The electrodes 12 and 13 can also be combined into a single electrode 57 according to the embodiment according to FIG.

In this case, the mode of operation is basically the same as in the case of the arrangement Fig. I by placing the left face 58 of the electrode 12 and the right face 59 of the electrode 13 corresponds. This single electrode S7 also combs in the manner shown in Figures 7 and 8 be constructed.

The tubes 10- will be on the inside with a silver coating 60 between the lines designated 6r and 62, the is at the same potential with the electrode 13. This coating affects relatively high positive voltage the cathode ray in such a way that it turns it on concentrated at every point of the storage electrode.

The tube ι ο is evacuated as much as possible.

Claims (6)

Patent claims: i. Method for converting one in the entirety of its brightness values a photocathode thrown image into a mosaic of electrostatic charges and scanning · by means of cathode rays, characterized in that the one coherent photoelectrically effective cathode released electrons on one opposite it, but arranged separately from it and with a the number of storage devices corresponding to the number of library points provided electrode arrangement (anode) are stored. 2. Facility for carrying out the procedure according to claim i, characterized in that the from the cathode ray The scanned anode consists of one or two metal screens arranged side by side, in the collector body isolated .einsetzt are in such a way that they are charged from the side of the photocathode and affect the cathode ray through their charges on the scanning side can. 3. Device according to claim 2, characterized characterized in that in front of the anlode assembly in the direction against the Cathode towards a positively charged electrode, e.g. B. is provided in the form of a fine-meshed network. 4. Device according to claim 2 and 3, characterized in that the entire Arrangement consisting of photocathode, anode arrangement to be scanned and network anode located on the daypr wide end of a Braunsehen tube is inserted so that on the photocathode the image can be projected from the outside. 5. device 'according to claim 2 to 4, characterized in that the anode * body consists of a net, in the mesh of which the charges are absorbed Collecting bodies are inserted insulated, 6. Circuit for a device according to claim 2 to 5, characterized in that that the anode scanned by the cathode ray to 'the positive and the photoelectrode to the negative pole of a Voltage source is connected and in 'the line between anode and voltage source a resistor 'is switched on, at which the when scanning the Anode caused by the cathode ray and 'the brightness values of the Voltage fluctuations corresponding to the image. 1 sheet of drawings