DE889904C - Circuit for the compensation of the interference signal in image storage tubes - Google Patents

Description

Circuit for compensating the interference signal in image storage tubes In the case of the television-like image decomposition by means of image storage tubes, there are also so-called interference signals are added to the image signals. The interfering signal is that which is intended electrical signal, which, to the undistorted image signals, for example obtained by scanning with a Nipkow disk and a photocell, added, results in the falsified signal form taken at the output of the image storage tube. Investigations into the interfering signal have shown that an essential component of the interfering signal, namely the so-called fixed component, is all the more pronounced occurs the closer the considered image zone is to the edge of the grid. As is well known takes place on the storage electrode by the at the respective point of impact of the A. scanning beam triggered and in diffuse distribution on the storage electrode returning secondary electrons a recharging process. As you get closer to the edge zone is apparently the density of the falling back onto the storage electrode Secondary electrons always lower. This decrease in density of the secondary electrons against the edge of the grid area is probably due to the fact that on the edge zones secondary electrons only from one side when the scanning beam approaches stand out; immediately after the scanning beam has passed, a will appear in the edge zone located surface element no longer hit by return electrons at all, because at this moment the tilting process begins., and the jet is going on at great speed. the other end of the line or the picture moves back. So there are only significantly less of the scanning beam on a surface element of the edge zone triggered returning secondary electrons are noticeable than on a surface element the middle zone of the grid. Furthermore, the immediately adjacent to the grid, but surface elements of the storage electrode no longer swept over by the scanning lever Pick up return electrons, thereby becoming more and more negative and finally one Reach negative equilibrium potential, which prevents the impact of further return electrons locks. The grid is thus framed by a strongly negative zone. These negative zone therefore has a repulsive effect on those approaching the edge zones of the grid Return electrons; these are therefore deflected towards the center of the grid.

Research has shown that this is due to the aforementioned circumstances The interference signal caused can be partially eliminated, for example by positive Pre-tensioning of a frame surrounding the scanned grid area. You can do this achieve that the interference signal amplitude over a relatively large part of the scanning area becomes practically zero, only at the beginning and end of the image or the image line is then there is still a residual interference signal amplitude, which is mostly that shown in FIG Owns shape.

The aim of the invention is to provide a simple and operationally safe switching arrangement to compensate for this disturbing residual signal amplitude.

According to the invention to compensate for the television-related Image transmission by means of image storage tubes, the interference signal that occurs is strongly negative pre-tensioned control grids of two amplifier tubes sawtooth vibrations opposite Polarity supplied, the operating point of the amplifier tubes and the amplitudes the sawtooth vibrations are chosen so that the tubes usually blocked only opened for a short time and in the curved characteristic area (eG / iA characteristic) controlled and the signals received at the output of the two amplifier tubes the signals picked up at the output of the image storage tube are mixed in.

The invention is described below with reference to FIG. 2, which shows an exemplary embodiment. To compensate for the static interference signal in the line direction, a sawtooth waveform of line frequency is generated in a sawtooth voltage supplying trigger circuit, which includes a pentode i, a charging capacitor 2, a charging resistor 3 of a few megohms and time constant elements 5 and 6, according to curve a. The adjustable resistor 6 is used to set the frequency of this oscillation. The discharge of the charging capacitor 2 is controlled with the aid of positive pulses fed to the control grid of the pentode i. The sawtooth vibrations a are fed to the control grid of a triode io via a coupling capacitor g. The operating point A of this triode io is, as can be seen from FIG. 3, selected in such a way that the triode io remains blocked during most of the sawtooth oscillations fed to the control grid and is only opened during the most positive parts of the sawtooth oscillation. As a result, only the relatively strongly curved part of the tube characteristic is controlled, and a signal according to curve b is picked up at the output of triode io or at terminals ii and 1.2. A branched off part of the sawtooth vibrations a is fed via a capacitive voltage divider circuit consisting of the capacitors 7 and 8 to a reversing tube 13- , in whose output circuit vibrations c of the same shape and frequency but opposite phase position as a arise. These oscillations c are via a coupling capacitor 1q. a triode 15 is supplied, which in the same way as the triode ro causes a deformation of the supplied pulses. The deformed pulses according to curve d are picked up between terminals 12 and 16. Additive mixing of the signals according to curve b and the signals according to curve d results in a signal course which is opposite to the course of the static interference signal s when the mutual phase position mentioned above is maintained. This compensation signal is used in a manner known per se to compensate for the interference signal.

The application of the method according to the invention is not restricted only on the compensation of the interfering signal in line direction, but can also with Advantageously, they can be used to compensate for the so-called image interference signal. While the static line interference signal is generally symmetrical with respect to the center of the line and therefore signals b and d are substantially the same size this symmetry usually does not exist in the case of the picture interference signal. In this case you have to the signals b and d have different amplitudes, which is reflected in a small Change in the operating conditions of an amplifier tube can be achieved easily.

Claims (1)

Claim: arrangement for compensating for that part of the interference signal that cannot be eliminated by means of positive frame biasing during television image transmission by means of image storage tubes, characterized by the simultaneous use of the following features: i. Two counter-rotating, in-phase sawtooth oscillations are fed to the heavily negatively biased control grids of two amplifier tubes in such a way that one sawtooth oscillation has a steep edge at the beginning. the line or the image, with the second sawtooth oscillation the steep edge -am (Eide of the line or the image occurs; 2. the operating point of the amplifier tubes and the amplitudes of the sawtooth oscillations are selected so that the blocked tubes only for short times, e.g. less than 18 of the oscillation period, opened and operated in the curved part of the grid voltage-anode current characteristic curve; 3. the signals received in the output circuits of the two amplifier tubes are mixed with the signals picked up at the output circuit of the image storage tube.