CS205366B1 - Connexion of deviation current collector in the television scanning generator - Google Patents

Description

The invention relates to the connection of a deflection current corrector in a TV decomposition generator, in particular to a corrector for correcting the shape of the timing of the generated sawtooth deflection current.

In the temporal decomposition of the television image, there is a distortion of geometry, among which the causes may include, in addition to imperfections of the deflection currents themselves, imperfections of other parts of the television imaging or reproduction system, such as deflection coils, electron optics, lenses and the like.

For color television sensing systems and several sensing tubes, there is a difference in the geometric distortion of the component images, which is the cause of the so-called opacity errors. The accuracy requirements for component image coverage are stricter than the basic image geometry requirements.

The decomposition generators typically comprise circuitry and circuit elements, allowing a partial adaptation of the shape of the deflection current over time so as to reduce the geometric distortion and / or cover errors. Usually, elements for adjusting the position, dimensions and linearity of the image are used for this adjustment. Linearity is understood to be the control of the magnitude of such a current correction component whose time course is in the form of a parabola with a peak approximately in the middle of the active electron beam deflection period.

Common drawback of all known solutions of correction circuits in decomposition

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205 360 generators are interdependent when adjusting said elements. As a result, the adjustment must be repeated several times. This manipulation is relatively difficult, which is particularly unfavorable when adjusting the relative coverage of the component images of a color television capture device. These drawbacks eliminate the deflection current correction circuitry in the TV decay generator, Ss. certificate number 169 623 and Ss. No. 176 959 · These connections allow independent adjustment of the correction of five elements for one deflection direction. The independence of the settings is determined by a certain order of adjustment of the controls assigned to the selected image locations, which is suitable for manually adjusting the coverage of the component images in the color television capture device when scanning the test pattern. However, with the introduction of an automatic opacity adjustment system using non-opacity information derived from suitable elements of the captured scene, the necessity to maintain a certain order when adjusting the opacity at selected areas of the image could be an obstacle. they may not appear in the desired order in the selected areas of the image.

The benefit of engaging the deflection current corrector according to the present invention is that it allows the deflection current correction to be adjusted gradually and possibly simultaneously for one of the two electron beam deflection directions so as to adjust the position of the image elements of each selected image location without changing the image position. elements in other selected areas of the image. Thus, it is possible to gradually correct the position of the image elements at selected points of the image in any order.

The principle of the bias current corrector according to the present invention is based on a series connection of at least two integrators, complemented by resistor systems that connect the individual control voltage leads to the nodes of the serial link integrators. In this connection, each control voltage input can be assigned a selected point in the image by changing the control voltage to change the position of the image elements assigned to the selected image point in one of the two electron beam deflection directions without changing the position of the image elements (

In the accompanying drawings, Fig. 1 shows an example of a corrector connection, Fig. 2 shows an example of the waveforms of the resulting correction current, and Fig. 3 shows an example of the integrator connection.

An example of a deflection current corrector connection according to the present invention is shown in FIG.

This involvement includes four integrators 31 and 32. 12 »34 ^each having input výetup and supply of the reset pulse. Further, the wiring comprises five control voltage leads 1, 2, 2 »ii 1, ⁸ five resistor systems 11. 12, 12, 14. 12» The input of the first integrator 31 is connected to the first wiring node 21, the output of the first integrator 31 is connected by the input of the second the integrator 32 passes through the second wiring node 22. the output of the second integrator 22e ee through the input of the third integrator 33 passes through the third wiring node 23. the output of the third integrator 33 connects the input of the fourth integrator 34 through the fourth wiring node 24 and the output of the fourth integrator 34 the supply of the first control voltage 1 is connected to the first set of resistors 11 with all the connection nodes, the supply of the second control voltage 2 is connected to the two nodes and connected to the second set of resistors 22, the supply of the third control voltage voltage 2 j® ³⁶ nodes connection wiring In the third set of resistors 12, the supply of the fourth control voltage 205 is connected to all wiring nodes 14 and the supply of the fifth control voltage 20 ^{to all} wiring nodes 15 is connected ^{to all} wiring nodes 15.

the wiring operation is based on the fact that the currents induced by the individual control voltages in the resistors connected between the individual control voltage inputs and the individual wiring nodes are integrated in series integrators. In the output node of the circuit, each individual current produces a component of the output correction current whose time dependence is a power function of time. The degree of each of the resulting power functions is determined by the number of integrators through which the supplied current passes. Each of the control voltages thus elicits a component of the output correction current whose time dependence is a function of the fourth stage and contains power members of the zero to the fourth stage. The resulting correction current passing through the last wiring node consists of the components induced by the individual control voltages and its time dependence is also a function of the fourth stage. This resulting correction current is added to the basic deflection current, which is fed directly or via the output amplifier to the deflection coils.

It is known that the function of the fourth stage is unambiguously determined by the functional values for the five values of the independent variable, in this case for five times. In the circuit according to the attached Fig. 1, the time course of the output correction current is determined by the values of the five control voltages. Each of the five control voltages can be assigned one of the five selected locations of the image so that the control voltage does not affect the positions of the image elements associated with the other four control voltages. The described effect of the control voltages is conditioned by using such values within the individual resistor systems that each of the control voltages produces a component of the resulting correction current having zero values at times corresponding to the locations in the image assigned to the other four control voltages. Then, for example, the first control voltage adjusts the correction of the position of the pixel elements at the first of the selected points of the image without affecting the positions of the pixel elements at the other of the five selected points of the image.

An example of specific time courses of components of the resulting correction current induced by individual control voltages is shown in the attached Fig. 2. These time courses are calculated from predetermined function values for the selected times.

ie = 0 t _g = 0.25 t ₃ = 0.5 t ₄ = 0.75 t ₅ 1 1

The time course of the first component of the resulting correction current 41 caused by the first control voltage has zero values at times t ₂ , tp t 1, t 1 and a unit function value at time t 1.

It is designed to * set the correction at the image location that corresponds to time tp the time course of the second component of the resulting correction current 42 caused by the second control voltage of my zero value at times tp tp t *, t ^ and has a unit function value at time t ₂ intended for setting the correction at the point of the image corresponding to the time t ₂ .

The time course of the third component of the resulting correction current 43 induced by the third control voltage has zero values at times tp t ₂ , t *, and has a unit function value at time tp It is intended to adjust the correction at the image corresponding to time tp

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The time course of the fourth component of the resulting correction current 44 caused by the fourth control voltage has zero values at times t 1, t g, ie, t 1, and has a unit function value at time t 1. It is intended to set the correction at the point of the image corresponding to the time t ^.

The time course of the fifth component of the resulting correction current j, induced by the fifth control voltage, has zero values at times t,, tg, tp t a and has a unit function value at time t.. It is intended to set the correction at the point of the image corresponding to the time t ^.

Unit function values at respective times for the individual components of the resulting correction current according to the appended Fig. 2 were selected for illustration. These functional values can be any range from positive to negative maximum. The resulting correction current may then have different waveforms corresponding to the zero to fourth degree functions. In the specific case of the appended Fig. 2, the sum of all components of the resulting correction current has a unit value at all times, so that the resulting correction current is DC with the unit value.

An example of a specific integrator connection is shown in the attached Fig. 3. The integrator input 51 is coupled to the inverting input of the operational amplifier 55, the non-inverting input of which is coupled to a conductor and zero potential. The integrating capacitor 54 is connected between the output of the opamp and the inverting input. A switching transistor 53 of the MOSFET type is connected in parallel to the integration capacitor 54. Its control electrode is connected and supplied with reset pulses 52. A conversion resistor 56 is connected between the output of the opamp and the integrator output 57.

The operation of the integrator begins in each cycle by terminating the reset pulse and thereby disconnecting the switching transistor 53 at the beginning of the active run of the deflected electron beam.

The integration capacitor 54 integrates the electrical charge supplied by the current passing through the integrator input 51 from the external circuits. With a significant amplification of the operational amplifier, the voltage at its inverting input is practically zero, so that the voltage of the integrating capacitor 54 corresponding to the integrated electric charge ee appears at the output of the operational amplifier 55. This voltage is converted by a resistor 56 into current passing through the integrator output 57 to external circuits. Upon completion of the deflection period of the deflected electron beam, the resetting pulse arriving at the resetting pulse 52 causes the switching transistor 53 to close, thereby discharging the integration capacitor 54, so that the integrator is ready for integration in the next cycle.

The number of integrators used in the bias current corrector circuit of the present invention is related to the desired accuracy of position correction of image elements over the entire image area. The number of integrators used is one increased number of selected points in the image. The optimum number of control voltages corresponds to the number of selected points in the image. A different number of control voltages may also be used, but with a lower number ee it will not utilize the possible accuracy of the correction, the excess control voltages will show a mutual dependence of their effect.

The usual correction accuracy achieved by commonly used adjusters, ie position, size and linearity, corresponds to two integrators, three selected points in the image and three independently acting control voltages.

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In some cases, it may be expedient that even with the optimum number of control voltages some of them act on the position of the pixel elements in more than one of the selected locations in the image. This is the case, for example, if only a reduced number of control voltages is sufficient for normal adjustment of the correction to compensate for instabilities during operation, while all control voltages are used for the basic adjustment of the correction over a longer period of time. resistors connecting the control voltage leads to the individual wiring nodes. For example, in the wiring shown in FIG. 1, if the resistances connecting the first, second, and third control voltages 1, 2, 2 ^{8 to the} first and second wiring nodes 21, 22 are omitted, the first three control voltages will also affect the position of the pixels. of the image for adjusting the correction by the fourth and fifth control voltages. However, neither the fourth control voltage nor the fifth control voltage will affect the position of the pixel elements at the points of the image to be adjusted by the first, second and third control voltages. If the basic correction setting is made first with the first, second and third control voltages and then with the fourth and fifth control voltages, the control independence is maintained. When adjusting the correction with only the first, second and third control voltages, the control independence is also maintained. In this case, it is desirable that this correction adjustment also applies to the threshing images intended to be adjusted by the fourth and fifth control voltages, which is achieved in the described adjustment of the corrector circuit.

The advantages of connecting the deflection current corrector according to the invention can be applied in cases where very good image geometry is to be achieved with easy correction control and in particular for automatic correction of the component image coverage in the color television capture device. that appear randomly in selected areas of the image.

Claims (1)

SUBJECT OF THE INVENTION A deflection current corrector connection in a television decomposition generator, characterized in that it comprises at least two integrators (31), (32) connected in series, the output of the preceding integrator being connected to the input of the following integrator, the input of the first integrator (31) being connected to the first wiring node (21), the connection of the first integrator (31) and the second integrator (32) passes through the second wiring node (22), the connection of the second integrator (32) to another integrator (33) passes through the third wiring node (23), the output of the last integrator is connected to the last wiring node, further comprising at least three control voltage supplies (1), (2), (3), wherein the first control voltage supply (1) is connected to at least one of nodes (21), (22), (23), the second control voltage supply (2) is connected to the second set of resistors (12) with at least one of and the connection (21), (22), (23), the third control voltage supply (3) is connected by a third set of resistors (13) to at least one of the connection nodes (21), (22), (23) and another control voltage supply it is connected to at least one of the connection nodes by a further set of resistors.