SU653773A1 - Device for vertical deflection of electron beams of self-monitoring kinescope - Google Patents

Claims (1)

connected between the second output of the frame scanner unit and the junction point of the second diodes of the first and second circuits. N. FIG. 1 shows the basic electrical circuit of the proposed device; in fig. 2 - diagrams of the current flowing in the device. The device for vertical deflection of a color kinescope electron beam with self-knowledge contains a vertical scanning unit 1, parallel to the outputs of which two serially connected personnel deflecting coils 2 and 3 are connected, and two parallel connected circuits, each of which contains a series-connected first diode 4, potentiometer 5 and according to the included second diode b, the anode of the first diode 4 of the first circuit is connected to the cathode of the corresponding first diode 4 of the second circuit, and the cathode of the second diode 6 of the first circuit is connected with the anode of the second diode 6 of the second circuit, and the moving contacts of the potentiometers 5 of both circuits are connected to the common connection point of the frame deflecting coils 2 and 3, the inductor 7 with two windings, the first of which is connected between the first output of the frame 1 unit and the first connection point diodes 4 of the first and second circuits, and the second winding of the inductor 7 is connected between the second output of the vertical scanning unit 1 and the connection point of the second diodes b of the first and second circuits. The device operates as follows. From the outputs of the vertical scanning unit 1, a current is applied (see FIG. 2a), which can be represented as a sum of a horizontal sawtooth current (see FIG. 26) and a horizontal parabolic current modulated with a personnel sawtooth signal (see FIG. 2c). At the same time, the amplitude of the horizontal parabolic current modulated by the personnel sawtooth signal (see fng. 2c) is an order of magnitude smaller than the amplitude of the personnel sawtooth current (see Fig. 26). The electrical parameters of the elements of the proposed device are pre-selected such that a large component of each of the currents (see Fig. 26) and (see Fig. 2b) passes through personnel deflection coils 2 and 3 and a smaller component of each of these currents circuit connected in parallel with these coils. The large frame saw component (see Fig. 26), the passage through the frame deflecting coils 2 and 3 in the same direction, creates in the deflection space of a color kinescope a bipolar magnetic field that performs a vertical deflection of the electron beams of the color kinescope. The large component of the horizontal parabolic current modulated with a personnel sawtooth signal (see Fig. 2c) also passes through personnel deflection rollers 2 and 3 in the same direction and creates a bipolar magnetic field deflecting electron beams vertically in the space of a color kinescope. color kinescope. But due to its shape and size, the component of the horizontal parabolic current modulated with a personnel sawtooth signal (see Fig. 2c) corrects the geometric distortions of the raster in the vertical direction. The small components of the personnel sawtooth current (see Fig. 26) and the horizontal parabolic current modulated with a personnel sawtooth signal (see Fig. 2c) pass through a circuit that is a series connection of the first winding of the inductance coil 7, parallel-connected circuits of diodes 4 and b and potentiometer 5 and the second winding of inductor 7. Pre-electrical parameters of these circuits are chosen such that the main resistance for the smaller component of the sawtooth current (see Fig. 26) is parallel to connected circuits of diodes 4 and 6 and potentiometer 5, and for the smaller component of a horizontal parabolic current modulated with a frame saw-tooth signal (see Fig. 2c), both inductance coil 7 are winding. This is possible because the frequency of a horizontal parabolic current modulated with a frame-like sawtooth signal (see Fig. 2c) is two orders of magnitude higher than the frequency of the personnel sawtooth current (see Fig. 26). Potentiometer 5 of the first parallel circuit with separation diodes 4 and b is distributed between personnel deflection coils 2 and 3 personnel sawtooth current (see FIG. 26) only for one half of the screen, upper or lower, and potentiometer 5 of the second parallel circuit with separation diodes 4 and b makes such a distribution, respectively, in the other half of the screen. The direction and magnitude of the distribution of the frame sawtooth current (see Fig. 26) between the cadre deflecting coils 2 and 3 is determined by the position of the moving contact of the corresponding potentiometers 5. Differing in magnitude by the magnitude of the frame sawing currents (see Fig. 26) in the cadre The blating coils 2 and 3 can be represented as a sum for one cadre deflection coil 2 or 3 and the difference for the other of these coils as a deflecting current and small in comparison with this current of the driving current. In this case, the deflecting current flows through the personnel deflecting rollers 2 and 3 in the same direction and performs the vertical deflection of the electron beams of the color kinescope, and the driving current flows through the personnel deflecting rollers 2 and 3 in opposite directions and creates the space of the color kinescope deviation is a four-pole magnetic field that moves in the vertical direction in opposite directions relative to each other the rays of the side illuminators of the kinescope. Due to the frame frequency and sawtooth of the driving current, this movement of the rays remains almost the same within the raster line, but varies within half of the screen from the maximum value on the upper or lower raster line to zero on the middle raster line, reducing or increasing the horizontal contour on the upper half of the screen or on the lower half of the screen. By selecting the direction and magnitude of the distribution of the frame sawtooth current between the frame deflecting coils 2 and 3 using one of potentiometers 5 for the upper half of the screen and using the other of these potentiometers 5 for the lower half of the screen, you can reduce the horizontal contours formed on the vertical axis of the screen screen beams lateral spotlights kinescope. The inductor 7 inductance distributes a horizontal parabolic current modulated with vertical sawing signals between personnel deflecting rollers 2 and 3 (see Fig. 2c). The direction and magnitude of the distribution of the horizontal parabolic current modulated by the personnel sawtooth signal (see Fig. 2c) between the vertical deflection coils 2 and 3 is determined by the position of the magnetic core of the inductor 7. The modulated lowercase parabolic currents differing slightly in magnitude in personnel deflection coils 2 and 3 can be represented as a sum for one personnel deflection coil 2 or 3 and the difference for the other of these current curbs, correcting the geometric distortions of the raster, and the current correcting error information. At the same time, the current correcting the geometric distortions of the raster flows through the frame deflection coils 2 and 3 in the same direction and corrects the geometric distortions of the raster in the vertical direction. A current that corrects convergence errors flows across personnel deflecting coils 2 and 3 in opposite directions and creates in the space of a color kinescope deflection a four-pole magnetic field that moves the rays of the side projectors of the kinescope in opposite directions to each other. Due to the fact that the current correcting convergence errors is a horizontal parabolic current modulated by a frame sawtooth signal (see Fig. 2c), this movement of the rays varies by a parabola within the raster line from the maximum value of one character on the upper raster line to maximum, the value of the opposite sign on the bottom line of the raster, reducing or increasing the arc horizontals at the corners of the screen. By selecting the direction and magnitude of the distribution of a horizontal parabolic current modulated with a personnel saw-tooth using the inductance coil 7, it is possible to correct the horizontal arc at the corners of the screen. Thus, the proposed device performs: the vertical deflection of the electron beams of the color kinescope; correction of geometric distortions of the raster in the vertical direction; data on the vertical axis of the screen horizontals formed on the screen by the rays of the lateral projectors of the kinescope; correction in the corners of the screen arcs of contour lines formed on the screen of the beams and side projectors of the kinescope. Compared with the known, the proposed device allows to improve the accuracy of mixing the corners of the contour horizontals formed by the side-beam projectors of the kinescope, for the following reasons: in the proposed device, the contour horizontals formed by the rays of the side projectors of the kinescope are not accompanied by the bends of these horizontals, so as the distribution of the modulated personnel signal horizontal parabolic current between the personnel from the clone rolls practically does not depend on the positions contact potentiometers that regulate the alignment of the horizontal contours on the vertical axis of the screen due to the inductance of the inductance coil introduced into the circuit; In the proposed device, the corners of the contours of the contours of the contours formed by the Lumi of the lateral illuminators of the kinescope are corrected for, with the fact that the modulation of the horizontal parabolic current modulated by the vertical uniform signal between the vertical deflection coils of the newly introduced coil inductance is regulated in this device. Apparatus of the Invention A device for vertical deflection of a color kinescope electron beam with self-knowledge, comprising a vertical scanning unit, parallel to the outputs of which two successively connected vertical deflection coils are connected, and two parallel connected circuits, each of which contains a series-connected first diode, a potentiometer and a second connected a diode, the anode of the first diode of the first circuit connected to the cathode of the corresponding first diode of the second circuit, and the cathode of the second diode of the first center The pi is connected to the anode of the second diode of the second circuit, and the moving contacts of the potentiometers both of their circuits are connected to a common connection point for personnel deflection coils, characterized in that, in order to improve the accuracy of convergence in the corners of the screen of the kinescope with vertical deflection, an inductor with two windings is inserted , the first of which is connected between the first output of the frame scanner unit and the connection point of the first diodes of the first and second circuits, and the second winding of the inductance is connected between the second output of the frame unit oh sweep and junction point of the second diodes of the first and second sources of information taken into account in the examination 1. I. Kaashoek. Deflection in the Roaxsystem Transactions BTR, V20, N4, 1974, p. 297. Uu