KR0137221Y1 - Error prevention circuit in sync. separating - Google Patents

Abstract

The present invention relates to a synchronization signal separation circuit of a video signal reproducing apparatus. In detail, even if a sag (SAG) is present in a vertical synchronization signal portion of a video signal, the synchronization signal separation error prevention prevents the occurrence of an error by accurately separating the synchronization signal. The present invention relates to a circuit comprising: a first synchronous signal separating means for separating a synchronous signal in an automatically gain controlled video signal, a second synchronous signal separating means for separating a synchronous signal in an automatic gain controlled video signal; Comparison means for comparing the magnitudes of the synchronous signals separated by the first synchronous signal separating means and the second synchronous signal separating means and outputting a switching signal, and a switching operation is selected by the switching signal of the comparing means, thereby providing a large value of the synchronous signal. It is made by providing a switching means for outputting.

Description

Synchronous signal separation error prevention circuit

1 is a conventional synchronization signal separation circuit diagram.

2 is a waveform diagram of each part of FIG.

FIG. 3 is an explanatory diagram of synchronization signal separation in the case where SAG in FIG. 1 is severe.

4 is a circuit diagram of one embodiment of the present invention.

FIG. 5 is an explanatory diagram of synchronization signal separation when SAG in FIG. 4 is severe.

* Explanation of symbols for main parts of the drawings

10: automatic gain control unit 20,20 ': low pass filter

30,30 ': Clamp 40,40': Synchronous separation

50: delay unit 60: automatic gain control detection unit

70: comparison unit 80: switching unit

100,100 ': means for separating synchronous signal

The present invention relates to a synchronization signal separation circuit of a video signal reproducing apparatus. In detail, even if a sag (SAG) is present in a vertical synchronization signal portion of a video signal, the synchronization signal separation error prevention prevents the occurrence of an error by accurately separating the synchronization signal. It is about a circuit.

The use of satellite broadcast receivers is increasing in order to receive various channels, to eliminate visual acuity, and to improve image quality. However, according to the types and broadcast conditions of satellite broadcast receivers, they have sags.

The sag of the video signal does not affect the sync signal separation when the sag is not severe according to the specification of the receiver, but when the sag is severe, the sync signal cannot be separated. Otherwise, the screen switching may not be performed properly by causing an error of the vertical synchronization signal, which is the standard of the screen switching.

That is, the conventional synchronization signal separation circuit is configured as shown in FIG. 1 so that an error occurs in which the synchronization signal is not properly separated when the sag is severe.

According to FIG. 1, the video signal is automatically controlled by the automatic gain control unit 10 and then applied to the video signal processing block. The video signal passes through the low pass filter 20 to separate the synchronization signal, The video signal passed through 20 is applied to the clamp unit 30 and is clamped, and the video signal passed through the clamp unit 30 is applied to the sync separating unit 40 to separate the sync signal.

The synchronization signal separated by the synchronization separation unit 40 is configured to be applied to the automatic gain control detection unit 60 together with the output of the clamp unit 30 while being applied to the synchronization signal detection output after the delay unit 50.

In the synchronous signal separation circuit having such a configuration, the video signal as shown in (a) of FIG. Signal is clamped to the feedback clamp voltage V1 at the clamp unit 30 through the inverter amplifier as shown in FIG. 2 (c), and applied to the sync separator 40 to use the sync slice level V2. By separating the synchronization signals, a synchronization signal as shown in FIG. 2 (d) can be obtained.

In the above case, the sag of the video signal is not severe, and in the case of the sag being severe, the screen disease error is generated because the desired synchronization signal cannot be separated.

That is, there is no problem of separation of sync signal when inputting normal video signal like (a) of FIG. 3 using the circuit of FIG. 1, but when video signal with severe sag is input like (b) of FIG. Although there is a slight difference, in the portion where the sag rises above the slice level as shown in (b) of FIG. 3, the sync signal is not separated and the sync signal is separated as shown in (c) of FIG.

Therefore, when the sag is severe, normal sync signal separation is not performed, causing a screen switching error due to a vertical sync signal error.

In view of the above, the present invention eliminates the synchronization signal error in which the synchronization signal is not separated even when the sag receives a severe broadcast, so that the screen switching is performed normally.

The present invention aims to prevent the screen switching part from the vertical sync signal error even when the sag receives a severe broadcast so that the sync signal which is the standard for screen switching like the normal screen is normally separated. First synchronous signal separating means for separating synchronous signals in the controlled video signal, second synchronous signal separating means for separating synchronous signals in the video signals that are not automatically gain controlled, first synchronous signal separating means and second synchronous And a switching means for comparing the magnitudes of the synchronous signals separated by the signal separating means and outputting a switching signal, and a switching means for selecting a switching operation by the switching signal of the comparing means and outputting a large value of the synchronous signal.

That is, the present invention configures another synchronizing signal separating means like the conventional synchronizing signal separating means to separate the synchronizing signal which is automatically gain controlled from each synchronizing signal separating means and the non synchronizing signal, and then compares the two signals in the comparing means. In comparison, by switching the switching operation of the switching means to select a large value of the synchronization signal, the normal synchronization signal can be separated even in a severe sag.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

4 is a circuit diagram of one embodiment of the present invention.

In a synchronous separation circuit configured with a synchronous signal separating means (100) for separating a synchronous signal among video signals automatically controlled by the automatic gain control unit (10), it is included in the video signal before being applied to the automatic gain control unit (10). A comparison unit including a synchronization signal separation means 100 'for separating the synchronized signal and comparing the magnitudes of the synchronization signals separated by the respective synchronization signal separation means 100 and 100' and outputting a switching signal ( 70 is provided, and the switching operation is selected by the switching signal of the comparator 70, and the switching unit 80 is configured to switch output a large value of the synchronous signal.

Here, the synchronizing signal separation means 100 and 100 'respectively include a low pass filter 20 and 20' for low-passing the video signal, and a clamp unit 30 for clamping the low-pass video signal to the feedback clamp level. 30 '), and the sync separation unit 40 (40') which separates the sync signal of the clamped video signal by the slice level.

That is, the technical configuration of the synchronization signal separation means 100 and 100 'is the same, but one synchronization signal separation means 100 is configured to connect and separate the synchronization signal among the video signals that are automatically gain controlled as before. The synchronization signal separating means 100 ′ is different in that it is configured to separate the synchronization signal among the video signals that are not automatically gain controlled.

However, the clamp level to be applied to the clamp unit 30 'of the present invention should be set slightly larger than the clamp level to be applied to the clamp unit 30. This is because it must be greater than the slice level.

The present invention of such a configuration is divided into various cases according to the video signal input state.

First, when the video signal is normally applied,

At this time, the synchronous signal separated by the synchronous signal separating means 100 and the synchronous signal separated by the synchronous signal separating means 100 'are applied to the comparator 70, respectively, but the video signal is normal. Since they do not operate, the synchronization signal levels are the same.

In this case, since the switching unit 80 does not generate the switching signal, the switching unit 80 outputs the synchronization signal separated by the synchronization signal separation unit 100. In this case, no problem occurs.

Second, if the video signal is large,

In this case, the synchronization signal passing through the synchronization signal separation unit 100 and the synchronization signal separation unit 100 'is applied to the comparison unit 70, but at this time, the video signal is large and the automatic gain control unit 10 is operated. The synchronization signal passing through the synchronization signal separation means 100 ′ is relatively larger than the synchronization signal passing through the signal separation means 100.

Then, the comparator 70 compares both signals to output a switching signal, and the switching unit 80 selects and outputs a synchronous signal of the synchronous signal separation means 100 ′ by the switching signal of the comparator 70. It will switch, and this does not cause a problem.

Third, if the video signal is small,

In this case, the synchronization signal passing through the synchronization signal separation unit 100 and the synchronization signal separation unit 100 'is applied to the comparison unit 70. At this time, the video signal is small so that the automatic gain control unit 10 is operated. The synchronization signal passed through the signal separation means 100 becomes relatively larger than the synchronization signal passed through the synchronization signal separation means 100 '.

Then, the comparator 70 compares both signals to output a switching signal, and the switching unit 80 switches to select and output the synchronous signal of the synchronous signal separation means 100 by the switching signal of the comparator 70. This is not a problem.

Fourth, when a PLL noise and a video signal of a small vertical synchronization signal are input (for example, there is no RF input and the synchronization signal level of the AV input is small),

In this case, the synchronous signal passing through the synchronous signal separating means 100 recognizes the PLL noise as a video signal to operate the automatic gain control unit 10, and subsequently has an effect of further reducing the input of a small synchronous signal when the video signal is input. ), Very little synchronization signal is applied.

However, since the sync signal passing through the sync signal separating means 100 ′ is larger than the sync signal passing through the sync signal separating means 100, the comparator 70 compares both signals and outputs a switching signal. In 80, the synchronous signal of the synchronous signal separating means 100 'is outputted by switching, and in this case, the case where a problem may occur may be compensated.

Fifth, when a video signal with severe sag is inputted,

In this case, first, the process of outputting the sync signal through the sync signal separating means 100 will be described with reference to the waveform diagram of FIG. 5.

As shown in (a) of FIG. 5, when a video signal with severe sag is input, the video signal passing through the automatic gain control unit 10 and the low pass filter 20 is as shown in FIG. Passing the unit 30 is as shown in (c) of FIG. 5 and passes it through the sync separation unit 40 again to output a sync signal as shown in (d) of FIG.

This synchronizing signal separation process separates the same synchronizing signal from the same process as the conventional synchronizing signal separation process, but sets a slice level such as A 'in FIG. 5 (c) and a low pass filter 20 such as B'. After passing through the boundary of the video signal, the synchronization signal becomes a duty DUTY as shown in C 'of FIG. 5 (d), resulting in a problem.

Next, referring to the process of separating the synchronization signal through the synchronization signal separating means 100 ', the slice level of A' in FIG. 5 (c) is different so that the synchronization signal 40 'normally outputs the synchronization signal.

The comparison unit 70 compares the synchronization signals separated by the respective synchronization signal separation means 100 and 100 ', but in this case, the synchronization signals separated by the synchronization signal separation means 100' have a large value. In the unit 70, the switching signal is output to the switching unit 80. Accordingly, the switching unit 800 switches and outputs the synchronization signal of the synchronous signal separation unit 100 ′. In this case, no problem occurs. .

As described above, the present invention eliminates the synchronization signal error in which the synchronization signal is not separated even when the sag receives a severe broadcast so that the screen switching is performed normally.

Claims (2)

First synchronous signal separating means for separating synchronous signals in the video signals with automatic gain control, second synchronous signal separating means for separating synchronous signals in video signals without automatic gain control, first synchronous signal separating means and first By comparing the magnitudes of the synchronous signals separated by the two synchronous signal separating means and outputting a switching signal, and a switching means for selecting a switching operation by the switching signal of the comparing means and outputting a large value of the synchronous signal; A synchronization signal separation error prevention circuit, characterized in that made. 2. The synchronization signal separation error prevention circuit according to claim 1, wherein the clamp level in the second synchronization separation means is set larger than the clamp level in the first synchronization separation means.