SU932648A1 - Device for time distortiones correction - Google Patents

Description

The invention relates to television technology and is used for recording and reproducing a full television signal on a magnetic tape. A device for correcting temporal distortions is known, which contains a set of definitely included (discrete) delay lines on a video signal transmission channel. At the same time, for the time of transmission of the active part of the line, such a set of lines is included each time, which corresponds to the leading edge of the horizontal sync pulse reproduced from the tape relative to the reference pulse t ОВ this device is the time interval between the horizontal sync pulse and the pulse generated by the reference pulse. the generator is coded with clock pulses, non-synchronous with the reference pulses, which leads to an additional residual error. The closest to the proposed technical entity is a time distortion correction device comprising a serially connected sync selector and a phase discriminator, a pulse shaper, a shaper of reset pulses, and Tak is also connected in series by a counter, a decoder, an intermediate memory block and a block of switched delay lines, the shaper input pulses are combined with the input of the reset pulse generator and connected to the second input of the phase discriminator, and the sync selector input is connected It is provided with an information input of a block of switched delay lines 23. However, the known device does not significantly reduce the residual time error due to the presence of variation in the delay time of switched delay lines relative to their nominal values OHfL

The purpose of the invention is to improve the accuracy of the correction of temporal distortion.

To achieve this goal, a time distortion correction device containing, in series, a connected synchronous selector and a phase discriminator, a pulse shaper, a shaper of reset pulses, as well as a serially connected counter, decoder, block of intermittent delay lines, moreover, the input of the pulse generator is combined with the input of the reset pulse generator and connected to the second input of the phase discriminator, and the input of the sync selector is connected to the information input the house of the block of switched delay lines, the series-connected prohibition pulse generator, the inverter and the first element AND, the series-connected delay block, the generator of linear-varying current, the block of the current and throttle current, the comparator and the second element And, the trigger, the generator of the installation current and the driver weight current, while the output of the sync selector is connected to the input of the inhibitor pulse generator, the output of the phase discriminator is connected to the input of the generator of linear-varying current, the input of the delay unit The input of the phase discriminator is connected to the input of the phase discriminator, and the output of the delay block is connected to the input of the phase discriminator, the second input of the first element is connected to the output of the pulse former, and the output of the first And element is connected to the control input of the decoder, the second input of the second element And is connected to the output of the former pulse inhibit, the third input is combined with the counter installation input and connected to the trigger output, and the output of the second element I is connected to the counter input of the counter, the trigger installation input is connected to the old output The counter is triggered, the reset input is three gers combined with the reset input of the counter and connected to the output of the reset pulse generator, the output of the weight current generator is connected to the output current of the setting current generator and connected to the second input of the current reading unit, and the inputs of the weight current generator are combined with the output current generator

The current inputs of the decoder are connected to the outputs of the counter, the input of the sync selector and the input of the driver

Claims (2)

the pulses are respectively the video signal inputs and the clock pulse input, and the second comparator input is the reference voltage input, while the weight current driver contains 2 n channels, the first n channels consisting of a series-connected key and an unregulated all-in input generator of which are supplied impulse from the input of reference impulses (plot 6, fig. 3). The current output signal, and the subsequent p channels consist of a key connected in series and an adjustable weight current generator, the outputs of all weight current generators are connected and are the output of the current circuit generator, and the control inputs of the keys are the corresponding inputs of the control signals. FIG. Figure 1 shows the structural electrical circuit of the proposed device; in fig. 2 is a structural electrical circuit of a weight current driver i in FIG. 3 timing diagrams explaining the operation of the device. The time distortion correction device contains a sync selector 1, a phase discriminator 2, a shaper 3 pulses, a shaper k reset pulses, a counter S, a decoder 6, a block of 7 intermediate memory, a block of 8 switched delay lines, a shaper 9 of inhibit pulses, an inverter 10, the first element And 11, a delay unit 12, a linearly varying current generator 13, a current subtraction unit It, a comparator 15, a second element AND 16, a trigger 17, a setting current generator 18 and a weight current driver 19, which consists of 2 n channels 20, the first The n channels consist of a key 21 and an unregulated weight current generator 22, and the subsequent n channels consist of a key 21 and an adjustable weight current generator 23. The device for the correction of temporal distortion works as follows. The video signal (plot d, fig.Z) is fed to the input of the sync selector 1. In the sync selector, the horizontal sync pulses are extracted (the diagram (G, Fig. 3) from the input video signal. From the sync output (helix, the horizontal sync pulses go to the input of the phase disc of the second 2). phase discriminator is the error voltage, the magnitude of which is proportional to the time interval between the leading edge of the reference pulse and the leading edge of the horizontal sync pulse. The output voltage of the phy discriminator goes to input This generator generates a current, the magnitude of which is proportional to the amplitude of the error voltage, the current form produced by the generator of linearly varying current, completely repeats the voltage form from the output of the phase discriminator and corresponds to the plot 2, FIG. 3. Restoration of the initial state of the phase discriminator and the generator of linear-varying current is produced by pulses produced by the delay unit 12 (epiyur ji, fig. 3). the input of which receives the reference pulses. From the output of the delay unit, these pulses are fed to the installation input to the initial state of the phase disc of the inverter and the generator of linearly varying current. For the duration of this pulse, both the phase discriminator and the generator of a linearly varying current are set to linear, i.e. in the operating mode, and in the intervals between the pulses in both schemes there are discharge processes. The intervals between these pulses are significantly longer than the duration of the pulses themselves, which ensures a complete restoration to the initial state from one cycle of measuring the residual error to another. The output of the generator of linear-varying current is connected to the input of the C unit of current subtraction, the other input of which is connected to the output of the generator of the set current and to the output of the former 19 weight currents. The keys 21 in all channels 20 of the forma l weight currents are identical and can: be performed on the diodes. Switched generators 22 and 23 weight currents form a current according to the binary law, according to which each successive ie. the higher bit of the weight current generator produces an output current whose value is two times higher than the weight current generated by the previous bit of the switched weight current generator. The control of switched weight current generators is performed from a counter 5 whose outputs are connected to the keys 21 of switched weight current generators in accordance with their weight, i.e. the low-order bit of the counter is connected to the low-order bit of the switched-on weight current generator, the high-level discharge of the counter is connected to the high-end bit of the switched weight current generator, and so on. The weight current-current driver and the set-up current generator form an input current in the input circuit of the current subtraction unit T, while at the second input of the current subtraction unit, a linear-varying current generates an output current. In the initial state, there are no currents at the output of the generator of linearly varying current and the output of the former of the weight currents. In the current subtraction unit, only the current of the generator of the installation current flows in, which is somewhat less than or equal to the current of the current-low-current weight generator. This current creates a potential at the output of the current deduction unit, which is proportional to this current and greater than the potential of the reference voltage (Eop), therefore, a zero potential is formed at the output of the comparator 15. With the arrival of the input phase discriminator 2. reference pulses from the generator output of a linearly varying current, a current arises that varies according to a linear law. At the moment when the potential at the output of the current subtraction unit becomes equal to the potential of the reference voltage, a positive potential occurs at the output of the comparator, which will be fed to the input of the second element I 16. If there are positive potentials, the other two inputs of the second element I will form at its output also a positive voltage drop, which will be fed to the counting input of the counter. At the output of the least significant bit of the counter, under the action of the input voltage drop, a potential is formed, which, acting through the switch 21 of the driver 19 of the weight currents, switches on the generator 22 of the weight current. The current subtracting unit will be supplied from the weighting current weigher –– a weigth current corresponding to the youngest bit in the dial of the switched weights of the current weights. 79 During the operation of the counter, a series of short pulses of binary code is formed at the output of the second element I. The pulse duration depends on the propagation delay time of the signal in the counter 5, the keys 21, the current subtraction unit I, the comparator 15 and the second element AND 1 The time error coding is performed in real time, therefore the period of the binary code pulses determines the discreteness of a set of switched delay lines i.e., the length of the short delay line of the time distortion correction device, and the total delay time is defined as the product of the number of code pulses by the discrete value of a set of mutable delay lines. At the moment when the leading edge of the horizontal sync pulse arrives at the input of the inhibitor impulse generator 9, a inhibit impulse is formed at its output (plot G, Fig. 3), the duration of which is longer than the impulse duration generated by the delay unit 12. The inhibit impulse arrives at the second input of the second element AND, locking it for the duration of this impulse. In this case, the process of encoding the time interval between the front of the reference pulse and the front of the line sync pulse ends, and the time interval is filled with binary code pulses (plot 6, Fig. 3). After the coding process is completed, the delay introduced into the transmission channel of the video signal being corrected is determined. as the difference between the maximum possible delay, the value of which is equal to the correction range of the device, and the delay, defined as the product of the number of code pulses and the discreteness of a set of switched delay lines. This means that if there are no code pulses, the maximum delay is introduced into the channel. The output voltage of the triggers of the intermediate memory block 7 is controlled by the keys of the block of 8 switched delay lines. In epure, fig. 3 shows the video signal that has passed the device's delay line. As can be seen from the figure, the keys are switched at the top of the line sync pulse. Moreover, there is no switch on the first line sync pulse of the 8 second switch, which indicates that the next line is or does not have a time offset from the previous one or this offset is less than the resolution (resolution) of the device. At the top of the next line sync pulse, the switching transition process is shown, since the number of code pulses at the output of the second element And 16 has changed. The delay time of the switched lines is distributed according to Law 2 and, therefore, are arranged in the following order:, 2Zr, 42G, StT, etc. With ideally produced delay lines, the transition from the total value of the video signal delay in the channel equal to (t: -2Т) to the delay 8Т introduces an additional delay into the channel equal to the discreteness of the set of delay lines, i.e. equal to / C. However, in the manufacture of delay lines, there are always deviations of the delay from the nominal value. The more these deviations, the greater the additional error in the temporal position of the corrected video signal will be introduced into the channel. In order for this error to have a permissible minimum value, it is necessary to make a line having a delay of 8 with an accuracy of no worse than 2-3. For transition-i and from delay (t + 2.t-) to delay 16, the accuracy of the line having delay iSt must be doubled again, and the line deviation of 32 t relative to its nominal value must be less than i. Obviously, the manufacture of the line with such accuracy is extremely difficult. To expand the tolerance for the spread, on the delay of lines installed in the higher bits, 1.5-2.0 times in the direction of increasing the delay relative to the nominal value and 3 times in the direction of decreasing the delay in relation to the nominal value, by performing adjustable generators 23 weight currents in older categories. Thus, the proposed device introduces temporal errors in the position of the code pulses having a sign opposite to the sign of the discreteness error of the series of delay lines included in the channel when the delay in the channel changes from a minimum value to a maximum. which allows reducing the residual value of the time error in the corrected video signal to a level equal to the discreteness of the set of delay lines, which advantageously casts it from the known device. Claim 1. A device for correcting temporal distortions containing a series-connected sync selector and a phase discriminator, a pulse shaper, a shaper of reset pulses, as well as a series-connected counter, a decoder, an intermediate memory block and a block of switched delay lines, the pulse shaper input combined with the input the pulse shaper is reset and connected to the second input of the phase discriminator, and the input of the sync selector is connected to the information input of the block switched x delay lines, characterized in that, in order to improve the accuracy of the correction, serially connected inhibit pulse shaper, inverter and first element And consecutively connected delay block, linear current generator, alternating current block, comparator and the second element And, the trigger, the generator of the installation current and shaper weighting, while the output of the sync selector is connected to the input of the inhibitor imprinter, the output of the phase discriminator is connected to the input of the generator linearly from I The input current, the input of the delay unit is combined with the input of the phase disc of the minator, and the output of the delay unit is connected to the INPUT of the installation of the phase discriminator, the second input of the first element I is connected to the output of the pulse former, and the output of the first element I is connected to the control input of the decoder, the second the input of the second element And is connected to the output of the inhibitor pulse generator, the third input is combined with the input of the meter installation and connected to the trigger output, and the output of the second element And is connected to the counter input of the counter, the input the trigger is connected to the high-end output of the counter, the trigger reset input is combined with the counter reset input and connected to the output of the reset pulse driver, the output of the current-flow generator is connected to the output current of the current-setting generator, and connected to the second input of the current-reading unit combined with the corresponding inputs of the decoder and connected to the outputs of the counter, the input of the sync selector and the input of the reset pulse generator are respectively the input of the video signal and the input th clock and the second input of the comparator is input to the reference voltage. 2. The device according to claim 1, characterized in that the weight current driver contains 2 n channels, the first n channels consisting of series, connected key and unregulated weight current generator, and the subsequent n channels consist of series-connected key and adjustable weight generator the current, while the outputs of all weight current generators are connected and are the output of the weight current generator, and the control inputs of the keys are the corresponding inputs of the control signals. Sources of information taken into account in the examination. 1.Goncharov A.V. and others. Technique magnetic video. M. Energy, 1978, pp. 266-229, 2. The UK patent No. 1.056.967, cl. H O B S / fO, H 0 N 5/78, 1967 (prototype). 4 4 P n  r well / r Y