SU758567A1 - Device for shaping colour synchronization signals of video tape recoder - Google Patents

Description

The invention relates to television technology and can be used in video recorders.

A device for generating color synchronization signals of VCRs containing a coincidence unit, a sync generator with three outputs, each of which is connected to a corresponding input of a modulating signal generator, the output of which is connected to the first input of the adder through a series-connected frequency-modulated generator and a high-frequency correction unit, and the second the adder input is connected to the sync signal output of the sync generator, while one of the inputs of the coincidence block is connected to the output of the block is high frequency correction, and the other input of the coincidence unit is connected to the output of the strobe signals of the color synchronization signals 9H of the clock generator Щ

However, the known device for generating signals. Color synchronization of a VCR has great complexity.

The purpose of the invention is to simplify the device.

To this end, a color synchronization signal generation device of a VCR containing a coincidence unit, a sync generator with three outputs, each of which is connected to a corresponding input of a modulating signal generator, the output of which is connected to the first adder input through a series-connected frequency-modulated generator and a high-frequency correction unit, and the second input of the adder is connected to the output of the clock signal of the clock generator, while 15 one of the inputs of the coincidence block is connected to the output of the block ysokochastotnoy correction, and the other input of the coincidence of pulses connected to the output signals tsve20 tovoy 9H clock synchronization, and administered five elements, the two flip-flop, two quartz oscillator, an OR gate and an inverter, wherein the input sync frequency moduli25 Rowan generator connected to the output. OR element, one of the inputs of which is connected to the output of the horizontal damping pulses of the clock generator via the first AND element connected in series, the second input of which is connected to the output of the strobe pulses of the color synchronization signals 9H, the clock generator, the second element AND, the first trigger and the third element AND, the second input of the element OR is connected to the output of the half-line frequency of the clock through a series-connected inverter, a fourth element And, a second trigger and a fifth element And, and the second inputs of the first trigger and t its element And are connected to the output of the first crystal oscillator, and the second inputs of the second trigger and the fifth element And are connected to the output of the second crystal oscillator, while the second input of the second element And is connected to the input of the inverter, and the second input of the fourth element And is connected to the output of the first element And .

The drawing shows a structural electrical diagram of the proposed device.

The device for generating color synchronization signals of video recorders contains a coincidence unit 1, a sync generator 2, a modulating signal generator 3, a frequency-modulated generator 4, a high-frequency correction unit 5, an adder 6, five elements 7, 8, 9, 10, 11, two triggers 12, 13, a first crystal oscillator 14, an OR element 15, an inverter 16, a second crystal oscillator 17.

The device operates as follows.

From the sync generator 2 to the shaper 3 of the modulating signal, horizontal damping pulses of the GIS, strobe pulses of color synchronization signals 9H, coming with a frame frequency and spanning from 7 to 15 and from 320 to 328 lines respectively in the first and second field of the image, are received and the half-line pulses are received. frequency of 7.8 kHz. The voltage at the output of the driver 3 corresponds to the required law of the frequency modulation of the color synchronization signals and the black field signal. Next, the signals pass through a frequency-modulated generator 4, block 5 high-frequency correction to the adder 6, where they are summed with the clock signal and fed to the outputs of the device. This signal is called the black field signal and represents the complete encoded signal of the SECAM system. It is used for synchronization. From the output of block 5, the signal is sent to block 1, to the second input of which there are strobe pulses of color synchronization signals 9H from the synchronizer 2. At the output of block 1, a color synchronization signal is obtained, which is mixed into the output signal of the VCR.

The frequency synchronization of the frequency-modulated generator is as follows.

The lowering damping pulses and strobe pulses of the color synchronization signals 9H are supplied to the first element And 7, the output of which receives a signal, then this signal is fed to the elements And 8, 10, the second input of which is supplied with inverted and non-inverted pulses of a half-line frequency of 7.8 kHz. At the output of elements And 8, 10, pulses are obtained that cover those portions of the color subcarrier on which the frequency-modulated oscillator 4 will be synchronized. These pulses are clocked using triggers 12, 13, the second inputs of which are oscillations of crystal oscillators 14, 17. At the output triggers 12, 13 pulses are coherent with the oscillations of the crystal oscillators 14, 17 and due to this at the outputs of the elements And 9, 11 are allocated vibration packets containing an integer number of periods of the reference frequencies. These signals are combined by the OR element 15 and fed to the synchronizing input of the frequency-modulated generator 4. Due to this, the oscillations of the generator 4 are synchronized with the stable frequency of the crystal oscillators d4, 17 during all lines, as well as during about 5 μs at the beginning of the color synchronization signals.

Thus, replacing the phase-locked loop frequency synchronization circuit of the frequency-modulated generator 4 to stabilize the quiescent frequencies at the black level greatly simplifies the device and increases its reliability.

Claims (2)

connected to the output of the strobe pulses of the 9H color synchronization signals, the synchronous generator, the second element AND, the first trigger and the third element AND, the second input of the element OR connected to the output of the semi-linear frequency of the synchronous generator through the series-connected inverter, the fourth element And, the second trigger and the fifth element And, the second inputs of the first trigger and the third element And are connected to the output of the first quartz oscillator, and the second inputs of the second trigger and the fifth element And are connected to the output of the second quartz oscillator, When the second input of AND Mo cerned connected to the input inverter and a second input of the fourth AND gate connected to the output of first I. The drawing shows a block circuit diagram of the proposed device. The device for forming color synchronization signals of video recorders contains a block 1 of coincidence, a synchronous generator 2, a shaper 3 of a modulating signal, a frequency-modulated generator 4, a block 5 of high-frequency correction, an adder 6, five elements And 7, 8, 9, 10 11, two triggers 12, 13, the first crystal oscillator 14, the element OR 15, the inverter 16, the second Quartz oscillator 17. The device operates as follows. From the synchronizing generator 2 to the shaper 3 of the modulating signal, enter the lowering damping pulses of the GMS, the 9H color burst signals, which follow the frame frequency and span from 7 to 15 and from 320 to 328 lines in the first and second image field, respectively, and half-line pulses . frequency of 7, 8 kHz. The voltage at the output of the driver 3 corresponds to the required law of frequency modulation of the color synchronization signals and the black field signal. The signals are then passed through a frequency-modulated oscillator 4, block 5 of the high-frequency correction to the adder 6, where they are added to the clock signal and fed to the outputs of the device. This signal is called the black field signal and is the complete coded signal of the SECAM system. It is used for synchronization. From the output of block 5, the signal is fed to block 1, to the second input of which the pulses of the 9H color synchronization signals from the synchro-generator are supplied 2. At the output of block 1, a color burst signal is obtained, which is kneaded into the output signal of the video recorder. The frequency of the frequency modulated oscillator is synchronized as follows. Lower quenching pulses and strobe pulses of color synchronization signals 9H are fed to the first element 7, the output of which receives a signal, then this signal goes to elements 8, 10, to the second input of which semi-linear frequency 7.8 kHz is applied. The output elements And 8, 10 receive pulses that cover those parts of the color subcarrier, which will synchronize the frequency-modulated oscillator 4. These pulses are clocked using triggers 12, 13, the second inputs of which are oscillations of quartz oscillators 14, 17. The output Triggers 12, 13 pulses are coherent with oscillations of quartz oscillators 14, 17, and due to this, oscillations containing an integer number of periods of reference frequencies are located at the outputs of elements 9, 11. These signals are combined by the element OR 15 and are fed to the clock input of the frequency-modulated oscillator 4. Due to this, oscillations of oscillator 4 are synchronized with the stable frequency of the quartz oscillators 4.4, 17 during all rows, as well as for approximately 5 µs at the beginning of color synchronization signals . Thus, replacing the phase-locked loop with the synchronization circuit of the frequency-modulated oscillator 4 to stabilize dormant frequencies at the black level greatly simplifies the device and increases its reliability. The invention of a color synchronization signal shaping device of a video recorder, comprising a matching unit, a synchronous generator with three outputs, each of which is connected to a corresponding input of a modulating signal generator, the output of which is connected to. the first input of the adder is via a serially connected frequency-modulated oscillator and a high-frequency correction unit, and the second input of the adder is connected to the sync generator clock output, while one of the coincidence block inputs is connected to the high-frequency correction block output, and the other coincidence block input is connected to the output of pulse gates synchronization 9H color synchronization, characterized in that, with the aim of simplifying the device by eliminating the automatic adjustment of the color Five And, two triggers, two quartz oscillators, an OR element and an inverter are introduced into the carriers. The synchronization input of the frequency-modulated oscillator is connected to the output of the OR element, one of the inputs of which is connected to the output of the horizontal damping pulses of the clock generator through serially connected the first element And, the second input of which is connected to the output of the strobe pulses of the color synchronization signals 9H of the synchronizing generator, the second element And, the first trigger and the third element And, the second input of the element OR is connected to the output the semi-line frequency of the sync generator through an inverter connected in series, the fourth And element, the second trigger and the fifth And element, and the second inputs of the first trigger and the third element And are connected to the output of the first crystal oscillator, and the second inputs of the second trigger and fifth element And are connected to the output the second crystal oscillator, while the second input of the second element And is connected to the input of the inverter, and the second input of the fourth element And is connected to the output of the first element I. Sources of information taken into account Pevzner and examination 1. BM TV color systems. M., Energie, 1969, p. 110 (prototype).