SU896793A1 - Colour synchronization device - Google Patents

Description

The invention relates to radio engineering and can be used in the color television technique.

Known color synchronization device containing a phase-shifting unit and a first relaxation generator, the input of which is connected to the output of the phase detector £ 1J.

However, the noise immunity of this device is low.

The purpose of the invention is to increase the noise immunity of the device.

This goal is achieved by the fact that a distribution block is introduced into the known color synchronization device, the first and second inputs of which are connected to the corresponding outputs of the phase-shifting unit, and the third input is connected to the first output of the first relaxation generator, and the first and second outputs of the distribution block are connected to the corresponding inputs of the phase detector.

In addition, the distribution block contains the first EXCLUSIVE OR element, the first input and the first output of which are the corresponding input and output of the distribution block, and the second EXCLUSIVE OR element, the first and second input, and the output of which are the corresponding inputs and output of the distribution block. In addition, a resonant coupler and a second relaxation generator are connected in series to the output of the relaxation generator, and the horizontal pulses are fed to the counting input thereof.

In FIG. 1 shows a structural electrical diagram of a device; in FIG. 2 - the same, second option.

The color synchronization device contains the first and second relaxation generators 1 and 2, a phase detector 3, a distribution block 4 with the first and second EXCLUSIVE OR elements 6, a phase-shifting block 7 and a resonant circuit 8, wherein the phase detector 3, the distribution block 4 and the phase-shifting block 7 combined into a frequency detector. 9.

The device operates as follows.

The inputs of the phase-shifting unit 7 are the signals of the color subcarrier. From the output of the phase-shifting unit 7, the signals through the distribution unit 4 are fed to the inputs of the phase detector 3.

Let on the first line the chrominance signal Д _{в is} supplied to the device, and the distribution block 4 is in such a state that a protective subcarrier packet passes to the first input of the phase detector 3, lagging in phase from the same packet arriving at the second input. The device remains in a static state for the duration of one line. Upon receipt of the next protective subcarrier packet, this time the phase shift sign will change, and the signal at the first input is ahead of the signal at the second input. The phase detector 3 goes over the entire time of the gating to the state when a logical unit is supported at its output. This signal passes to the counting input of the first relaxation generator 1, which goes into the second state. At the same time, its output signal switches over the distribution block 4. Therefore, on the third line, when component D g is received, the signal at the first input of the phase detector 3 is ahead of the signal at the second input, and a positive pulse is again output that changes the state of the first relaxation generator 1 and simultaneously the state of the distribution block 4. Thus, as long as the SECAM signal is received, the first relaxation generator 1 generates a half-line frequency voltage wave that is rigidly connected to the phase switching on the transmitting side. This signal, either directly or through the resonant circuit 8 and the second relaxation generator 2, is supplied to the electronic switch in the color channels of the decoder, providing switching of the color signals with the correct phase.

When the resonant circuit 8 and the second relaxation generator 2 are introduced into the proposed device, short-term failures caused by the loss of individual identification signals do not affect the shape of the output signal, since the control of the second relaxation generator 2 by its counting input is maintained.

$ An increase in noise immunity is achieved due to the fact that the proposed device, upon receipt of an identification signal at its input, is automatically switched so that on the next line the signal does not pass to the output of the device with the same frequency. Therefore, the proposed device continues to work with the correct phase even when a sinusoidal interference is applied to the useful signal.

Claims (3)

The invention of fire technology and technology can be used in a color gelation technique. The known color burst device containing the phase-matching unit and the first relaxation generator, the input of which is connected to the output of the phase detector 1 However, the noise immunity of this device is low. The purpose of the invention is to increase the noise immunity of the device. This goal is achieved by introducing a distribution block into a known color synchronization device, the first and second inputs of which are connected to the corresponding outputs of the phase-shifting block. The third input is connected to the first output g of the first relaxation generator, and the first and second outputs of the distribution block are connected to the corresponding the inputs of the phase detector. In addition, the distribution block contains the first EXCLUSIVE OR element, the first input and first output of which are the corresponding input and output of the distribution block, and the second element EXCLUSIVE OR, the first and second input, and the output of which are the corresponding inputs and output of the distribution block. In addition, sequentially connected resonant coatures and a second relaxation generator are connected to the output of the relaxation generator, to the counting input of which horizontal pulses are applied. FIG. I presents a structural electrical circuit of the device; Fig 2 is the same, the second option. The color synchronization device contains the first and second relaxation generators 1 and 2, phase detector 3, distribution block 4 with the first and second elements EXCLUSIVE OR 5 and 6, phase motor moving block 7 and resonant circuit 8, with phase defector 3, distribution block 4 and The faerous block 7 is combined into a frequency detector, 9. The device operates as follows. The signals of the color subcarrier are supplied to the inputs of the phase-shifting unit 7. From the output of the phase unit of the moving unit 7, the signals through the distribution unit 4 arrive at the inputs of the phase detector 3. Let the device receive a color signal Dd on the first line, and the distribution unit 4 is in such a state that a protective packet passes to the first input of the phase detector 3 subcarrier, lagging in phase from the same packet arriving at the second input. The device remains in a static state for the duration of one line. When you receive the next protective package with the following, this time D | the phase shift sign changes, and the signal at the first input advances the signal at the second input. Phase detector 3 switches to the entire gating time in a state where a logical unit is maintained at its output. This signal passes to the counting input of the first relaxation generator 1, which goes to the second state. At the same time, its output signal Turns on the distribution unit 4. Therefore, on the third line, when the component D g is received, the signal at the first input of the phase detector 3 leads the signal at the second input, and a positive pulse is again released at the output, changing the state of the first relaxation signal generator 1 and at the same time the state of the distribution block 4. Thus, as long as the SECAM signal is received, the first relaxation generator I produces a voltage wave of a semi-line frequency, rigidly connected with Zoe switching on the transmitter side. This signal, either directly or through the resonant circuit 8 and the second relaxation generator 2, is fed to the electronic switch in the color channels of the decoder, ensuring the switching of the color signals with the correct phase. When introducing into the proposed device the resonant circuit 8 and the second relaxation generator 2, short-term failures caused by the loss of individual identification signals do not affect the output waveform, since the control of the second relaxation generator 2 by its counting input remains. The effect of interference is achieved due to the fact that the proposed device, when a recognition signal arrives at its input, is automatically switched so that on the next line the signal with the same frequency does not pass to the output of the device. Therefore, the proposed device continues to operate with the correct phase even when applying a sinusoidal interference to the useful signal. 1. Color synchronization device containing a phase-shifting unit, the first relaxation generator, the input of which is connected to the output of the phase detector, characterized in that, in order to increase the noise immunity, a distribution unit is inserted, the first and second inputs of which are connected to the corresponding codes of the phase-shifting unit, and the third input is connected to the first output of the first relaxation generator, and the first and second outputs of the distribution block are connected to the corresponding inputs of the phase g technician. 2. The device according to claim 1, wherein the distribution unit contains the first element EXCLUSIVE OR, the first input and first output of which are the corresponding input and output of the distribution unit, and the second element EXCLUSIVE OR The first and second inputs, and the output of which are the corresponding inputs and output of the distribution unit. 3. The device according to p. I, is connected with the fact that sequentially connected resonant circuit and the second relaxation generator are connected to the expander of the relaxation generator, to the counting input of which horizontal pulses are applied. Sources of information taken into account in the examination 1. French patent number 1306659, cl. H 04 N / 44, 10.09.62 (prototype). |, vw 1 Figg