DE665701C - Arrangement for the compensation of the interference signal occurring in cathode ray image scanners for television purposes - Google Patents

Description

Arrangement for the compensation of the cathode ray image scanners for Interfering signal that occurs for television purposes, when viewed from a cathode ray scanner receives the TV picture supplied, a so-called interference signal can be observed, d. H. a brightness distribution that does not occur in the original image. This Rather, the interference signal also occurs on the receiver side when the original image emerges consists of an evenly white or gray area. The physical cause for this interfering signal is unknown. It has only been found that the same thing occurs in addition to the brightness signals that correspond to the original image and that it varies, for example, with the hardness and the current strength of the scanning beam is. It has been proposed to compensate for this interference signal in that on the transmitter side, for example, before modulating a high-frequency transmitter with the Output signals of the cathode ray scanner mixes a signal which is used for each coordinate from a sawtooth of the relevant coordinate frequency as well as from a sine of this and a sine of double the frequency. Any of these three Components must be adjustable according to amplitude and phase, so that for production of the compensation signal corresponding to the specific operating conditions twelve variables must be set. It has also been proposed that the interfering signal thereby to compensate that you have an auxiliary image, its brightness distribution of the distribution of the interfering signal, synchronous and in phase with the movement of the scanning The cathode ray scans and the voltages supplied by the photocell mixes with the output voltages of the cathode ray scanner. It is finally has been proposed to erieugen a compensation signal that a plurality voltage generator that can be set independently of one another, for example secondary emission-capable Electrodes of a cathode ray tube are used, the certain districts of the Scanned television picture are assigned and an ini essential in this district generate effective compensation signal.

According to the invention, a compensation device is to be designed in this way that a change in the size of the interfering signal occurring at an image point automatically a compensating and essentially on the relevant image point triggers limited additional signal, which is mixed with the image signals.

An embodiment of the invention is first illustrated with reference to Fig. I explained.

In Fig. I, io means a cathode ray scanner, its screen i i is photoactivated on the side facing the cathode ray tube 12. on The image 14 to be transmitted is thrown on this screen by means of the objective 13. With a lens 15 is referred to, which the object 1q. on a photocell panel 16 out in total projected about 25 photocells. A Braunsche Receiving tube is denoted by 17; its luminescent screen is via a lens 18 shown on a second photocell panel i9.

The arrangement according to Fig. I works in such a way that the photocell of the panel 16 and the panel i9 are assigned to one another in pairs, namely in such a way that each photocell in the panel 16 corresponds to the photocell of the panel in the same position i9 is combined. The anode currents of the two photocells act on each other contrary, so that a current is produced in the comparative apparatus VA in Fig. i, which corresponds to the size of the interference signal at the relevant image point. These is explained by the fact that on a photocell of the panel 16 only your Corresponding to the brightness value of the original image at the relevant image point Luminous flux acts and on the assigned photocell of the panel i9 of the Braun's receiving tube 17 delivered luminous flux. This receiving tube will, however fed with the output voltages of the sampler io and therefore contains on their Also shield the interfering signal. The brightness value of the relevant point on the object 14 is therefore present in both photocell streams and stands out in the comparison apparatus VA out. The apparatus VA thus only supplies a current or a voltage, which corresponds to the size of the interfering signal at the relevant image point.

Depending on this current or this voltage, the Apparatus ZS produced an additional signal, its distribution over time of the interfering signal. This additional signal is in a mixer MS with mixed with the voltages supplied by the scanner, so that any change in the Disturbance signal distribution automatically compensates and essentially on the relevant image area triggers limited additional signal, which the change in Noise signal distribution cancels again.

Fig. 2 shows an example of how the devices VA, ZS, MS in Fig. i can basically be executed. In Fig. 2, 2o means a photo line of panels 16 and 21 one of panels i9. A common resistance 22 is caused by the currents of these two photocells in opposite directions. durchflos§en, and 23, 24 are two suction voltage sources for the two photocells. 25 is a cathode ray tube, the second anode of which is indicated by 26 and which a number of secondary emissive electrodes equal to the number of Photocells in tables 16 and 19 are included. These electrodes are with 27 to 3i. The anode 26 is via a DC voltage source 32 and a Resistor 33 grounded. The voltage drop across resistor 33 becomes the grid an amplifier tube 34 and the voltage drop across a resistor 35, which is traversed by the output currents of the cathode ray scanner, the grid an amplifier tube 36. The anode currents of the tubes 34 and 36, their anode voltage sources finite 37 and 38 are denoted, flow through a resistor 39 in opposite directions Directions through. The circuit containing tubes 34 and 36 can be attached to a suitable one Place, if necessary via a DC voltage source, and it can also in the grid circles of one or both tubes 34,36 grid bias sources to be on.

The arrangement according to Fig. 2 works in such a way that the resistor 22 a voltage drop occurs, which corresponds to a change in the interference signal that has occurred at the relevant image point to which the resistor 22 is assigned. Accordingly, the potential of the secondary emissive electrode 27 and thus also the secondary emission current, which from this electrode after all Electrodes common secondary emission anode 26 flows, influenced. Also the voltage drop at resistor 33 is thus a measure. for changing the size of the interfering signal, and the anode current of the tube 34 therefore also changes. At resistance 39 occurs therefore there is again a voltage drop which only corresponds to the image brightness.

It should also be noted that the arrangement VA in Fig. 2 for each Photocell pair must be particularly available. The lines 4o lead to the arrangements VA for electrodes 28 to 3o.

Claims (3)

PATENT CLAIMS: i. Arrangement for the compensation of the cathode ray image scanners interference signal occurring for television purposes, characterized in that an A change in the size of the interference signal occurring at an image point automatically compensating and essentially limited to the relevant image area Triggers additional signal, which is mixed with the image signals. 2. Arrangement according to Claim i, characterized in that the object to be scanned (14) and the from a control receiver (17) from the currents supplied by the scanner (io to -12) obtained image each to one Photocell area (16 or i9) thrown and depending on the difference in the anode current, two of the same Photo cells assigned to the image area control the size of the additional signal. 3. Arrangement according to claim 2, characterized in that depending on the anode current difference every two photocells (2o or 21) of the surfaces (16 or i9) the potential of one secondary emissive electrode (27 to 31) of a cathode ray tube (25) influenced whose beam is synchronous and in phase with the cathode ray of the scanner s (io to 12) is deflected.