JPH0779413A - Time base collector circuit - Google Patents

Abstract

PURPOSE:To form a time base collector circuit in which a time base error with respect to a color signal is continuously corrected. CONSTITUTION:An input video signal is delayed by a variable delay line circuit 2, and the phase of the video signal delayed by the variable delay line circuit 2 is controlled and outputted by a variable phase control circuit 7. The phase of a horizontal synchronizing signal separated from the video signal delayed at the variable delay line circuit 2 and the phase of a reference horizontal synchronizing signal are compared by a phase comparator circuit 4, whose output is used to control a delay time by the variable delay line circuit 2 and a variable delay line 6 delays a reference NTSC signal. The phase of the delayed reference NTSC signal and the phase of the reference NTSC signal are compared at a phase comparator circuit 8, whose phase comparison output is outputted as a signal for phase control to a variable phase control circuit 7 and the phase control circuit 9 controlling the phase of the delayed reference NTSC signal.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a time base collector circuit for correcting a time base error of a video signal.

[0002]

2. Description of the Related Art A conventional time base collector circuit is shown in FIG.
As shown in, the phase comparison circuit 4 compares the reference horizontal synchronization signal output from the standard signal generation circuit 1 with the horizontal synchronization signal separated from the video signal via the variable delay line circuit 2 in the synchronization separation circuit 3. Then, the delay time of the variable delay line circuit 2 is controlled based on the phase comparison output, the time base error of the luminance signal in the video signal is corrected, and the video signal output from the variable delay line circuit 2 is subjected to variable phase control. Circuit 7
Output through.

On the other hand, the burst gate circuit 11 extracts a burst signal from the video signal output from the variable delay line circuit 2, and the extracted burst signal, the reference NTSC signal output from the standard signal generation circuit 1, and the phase comparison circuit. 1
2 performs phase comparison, the sample hold circuit 13 samples the phase comparison output by the separated horizontal synchronization signal, and controls the phase of the video signal input to the variable phase control circuit 7 based on the sampled phase comparison output. Was there.

[0004]

However, in the above-mentioned conventional time base collector circuit, the phase control in the variable phase control circuit is performed on the basis of the color burst signal included in the video signal, so that it is intermittent. There is a problem in that it is not possible to correct a time base error that has occurred in a part other than the part corresponding to the color burst, which is control. As a result, color unevenness has occurred.

An object of the present invention is to provide a time base collector circuit capable of continuously correcting a time base error for a color signal.

[0006]

In the time base collector circuit of the present invention, an input video signal is delayed by a first variable delay means, and the phase of the video signal delayed by the first variable delay means is a first variable phase. Controlled by the control means, the first
The horizontal synchronizing signal separated from the video signal delayed by the variable delay means and the reference horizontal synchronizing signal are compared in phase by the first phase comparing means, and the delay time by the first variable delay means is controlled based on the phase comparison output. A second variable delay means for delaying the reference NTSC signal based on the phase comparison output of the first phase comparison means in the time base collector circuit for outputting the video signal phase-controlled by the first variable phase control means; Reference N delayed by variable delay means
Second variable phase control means for controlling the phase of the TSC signal,
A second phase comparison between the reference NTSC signal and the output of the second variable phase control means and a phase comparison output as a signal for phase control by the first and second variable phase control means.
And phase comparison means.

[0007]

In the time base collector circuit of the present invention, the input video signal is delayed so that the horizontal sync signal separated from the output video signal from the first variable delay means and the reference horizontal sync signal are in phase synchronization, and the input video signal is delayed. The time base error of the luminance signal in the signal is corrected. The reference NT by the second variable delay means based on the phase comparison output by the first phase comparison means.
The SC signal is delayed. Based on the phase comparison output of the second phase comparison means of the reference NTSC signal and the delayed reference NTSC signal, the second variable phase control means causes the phase of the delayed reference NTSC signal to be synchronized with the phase of the reference NTSC signal. And the phase of the video signal is controlled by the first variable phase control means based on the phase comparison output of the second phase comparison means, and the color signal in the input video signal is converted by the delay by the first variable delay means. The added timebase error is corrected. Therefore, the correction is also performed for the time base error with respect to the color signal generated in the period other than the burst signal. That is, the time base error of the color signal is continuously corrected.

[0008]

EXAMPLES The present invention will be described below with reference to examples. FIG. 1 is a block diagram showing the configuration of an embodiment of the present invention.

The time base collector circuit of the present embodiment comprises a luminance signal time base error correction unit 10 for correcting a time base error contained in a luminance signal, and a color correcting a time base error contained in a color signal. It is composed of a signal time base error correction unit 20.

The luminance signal time base error correction unit 10 includes a variable delay line circuit 2, a sync separation circuit 3, a phase comparison circuit 4,
It is composed of a voltage controlled oscillator circuit 5 and a variable delay line circuit 6. The color signal time base error correction unit 20 is composed of a variable phase control circuit 7, a phase comparison circuit 8 and a variable phase control circuit 9.

The input video signal (Vin) is passed through the variable delay line circuit 2 to be delayed, and the video signal (Voh) delayed and output from the variable delay line circuit 2 is separated from the sync separation circuit 3.
The horizontal synchronizing signal (Hx) is separated by. On the other hand, the standard signal generating circuit 1 generates a reference NTSC signal (Sc) and a reference horizontal synchronizing signal (Href). The reference horizontal synchronizing signal (Href) output from the standard signal generating circuit 1 and the horizontal synchronizing signal (Hx) separated in the synchronizing separating circuit 3 are phase-compared in the phase comparing circuit 4, and the phase comparing circuit 4
The phase comparison output (Vph) output from the voltage control oscillator circuit 5 is supplied to the voltage controlled oscillator circuit 5 as a frequency control voltage to control the oscillation frequency (f _TBCH ) of the voltage controlled oscillator circuit 5.

The oscillation output from the voltage controlled oscillator circuit 5 is supplied to the variable delay line circuit 2, and the delay time of the variable delay line circuit 2 is controlled based on the oscillation frequency (f _TBCH ) of the voltage controlled oscillator circuit 5. The delay time for the input video signal (Vin) is controlled. Reference NT output from the standard signal generation circuit 1
The SC signal (Sc) is supplied to the variable delay line circuit 6, and the oscillation output from the voltage controlled oscillator circuit 5 is also supplied to the variable delay line circuit 6, based on the oscillation frequency (f _TBCH ) of the voltage controlled oscillator circuit 5. Control the delay time of the variable delay line circuit 6
The delay time for the TSC signal Sc is controlled.

Here, the variable delay line circuit 2 and the variable delay line circuit 6 have the same oscillation frequency (f
The delay time of the variable delay line circuit 2 and the delay time of the variable delay line circuit 6 have the same characteristics with respect to _TBCH ). By controlling the delay time with respect to the reference NTSC signal (Sc), the reference NTSC signal (Sc) is modulated by the oscillation frequency (f _TBCH ) of the voltage controlled oscillator circuit 5.

The video signal (Voh) output from the variable delay line circuit 2 is supplied to the variable phase control circuit 7 to control the phase to correct the time base error (Vo).
Output as c). The phase comparison circuit 8 compares the phase of the reference NTSC signal (Sc) with the output (Scoc) from the variable phase control circuit 9. The phase comparison output (Vphc) output from the phase comparison circuit 8 is supplied to the variable phase control circuits 7 and 9, the variable phase control circuit 7 controls the phase of the video signal (Voh), and the variable delay line circuit 6 modulates it. The variable phase control circuit 9 controls the phase of the selected reference NTSC signal (Sc).

Here, the variable phase control circuit 7 and the variable phase control circuit 9 have the same phase comparison output (Vp) of the phase comparator 8.
The phase amount controlled by the variable phase control circuit 7 and the phase amount controlled by the variable phase control circuit 9 have the same characteristics with respect to hc).

The operation of this embodiment configured as described above will be described. The input video signal (Vin) is, for example, a luminance signal (Vy (t + Δ
t)) and a color signal without a time base error (Vcφ
It is assumed that the signal is a combination of (t)).

The horizontal sync signal (Hx) separated from the video signal (Voh) by the sync separation circuit 3 contains a time base error component (Δt). Phase comparison circuit 4
Then, the horizontal synchronizing signal (Hx) and the reference horizontal synchronizing signal (Hre
f) and the phase comparison output (Vph) output from the phase comparison circuit 4 is a difference component between the horizontal synchronizing signal (Hx) and the reference horizontal synchronizing signal (Href), and is a time base error component (Δt). ) Itself.

The oscillation frequency (f _TBCH ) of the voltage controlled oscillator circuit 5 is controlled by the phase comparison output ( _Vph ). The voltage controlled oscillator circuit 5 is set so that the oscillation frequency (f _TBCH ) increases when the phase comparison output ( _Vph ) increases and the oscillation frequency (f _TBCH ) decreases when the phase comparison output ( _Vph ) decreases. ing. In the variable delay line circuit 2, when the oscillation frequency (f _TBCH ) of the voltage controlled oscillation circuit 5 increases, the delay time is controlled to be short, and the oscillation frequency (f _TBCH )
When is decreased, the delay time is controlled to be long.

As a result, the time base error (Δt) included in the luminance signal in the input video signal (Vin) is controlled in the variable delay line circuit 2 so as to be canceled, and the luminance signal of the video signal (Voh) is changed. The luminance signal ( _VOHY (t)) is the time base error corrected.

However, since there is no time base error in the color signal (Vcφ (t)) in the input video signal (Vin), the time base error is added to the color signal by passing through the luminance signal time base error correction unit 10. (-Δt) will be added. Therefore, the normal color signal cannot be reproduced as it is.

However, the delay time of the reference NTSC signal (Sc) is controlled in the variable delay line circuit 6 based on the oscillation frequency (f _TBCH ) of the voltage controlled oscillator circuit 5. However, the variable delay line circuit 6 is a variable delay line circuit having the same characteristics as the variable delay line circuit 2. Therefore, the reference NTSC signal (S
The correction component (-Δt) of the time base error is added to the variable delay line circuit 6 also in c), so that the video signal (Vo) is output to the output (Scoh) of the variable delay line circuit 6.
The same time base error as the color signal component (Vohcφ (t−Δt)) in h) is included.

The output (Scoh) of the variable delay line circuit 6 is passed through the variable phase circuit 9 to the reference NT in the phase comparison circuit 8.
The phase is compared with the SC signal (Sc). Therefore, the phase comparison output (Vphc) output from the phase comparison circuit 8 is a signal corresponding to the time base error (-Δt), and the phase of the input in the variable phase control circuits 7 and 9 is controlled by the phase comparison output (Vphc). To be done.

When the phase comparison output (Vphc) increases, that is, when the phase advances due to a time base error, the phase of the output signal is delayed. When the phase comparison output (Vphc) decreases, that is, when the phase is delayed due to a time base error, The phase of the output (Scoh) from the variable delay line circuit 6 is controlled so as to advance the phase of the output signal, and the time base error (-) generated in the luminance signal time base error correction unit 10 by the phase comparison output (Vphc). Δ
t) is corrected.

On the other hand, also in the variable delay line circuit 2, the phase of the video signal (Voh) output from the variable delay line circuit 2 is controlled by the phase comparison output (Vphc). Here, since the variable phase control circuit 7 and the variable phase control circuit 9 have the same characteristics, the luminance signal time base is set to the color signal component (Vohcφ (t−Δt)) in the video signal (Voh). The phase error due to the time base error (−Δt) generated in the error correction unit 10 will be corrected.

[0025]

As described above, according to the time base collector circuit of the present invention, the reference NTS is applied by the second variable delay means based on the phase comparison output by the first phase comparison means.
The C signal is delayed, the delayed reference NTSC signal and the reference NTSC signal are phase-synchronized, and the phase of the video signal is controlled by the first variable phase control means based on the phase comparison output of the second phase comparison means. Therefore, there is an effect that the time base error added to the color signal in the input video signal is continuously corrected by the delay of the first variable delay means. As a result, there is also an effect of suppressing the occurrence of color unevenness.

[Brief description of drawings]

FIG. 1 is a block diagram showing the configuration of an embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration of a conventional example.

[Explanation of symbols]

 1 Standard Signal Generation Circuit 2 and 6 Variable Delay Line Circuit 3 Sync Separation Circuit 4 and 8 Phase Comparison Circuit 5 Voltage Control Oscillation Circuit 7 and 9 Variable Phase Control Circuit 10 Luminance Signal Timebase Error Correction Unit 20 Color Signal Timebase Error Correction Unit

Claims (1)

[Claims] 1. An input video signal is delayed by a first variable delay means, and a phase of a video signal delayed by the first variable delay means is controlled by a first variable phase control means.
The horizontal synchronizing signal separated from the video signal delayed by the variable delay means and the reference horizontal synchronizing signal are compared in phase by the first phase comparing means, and the delay time by the first variable delay means is controlled based on the phase comparison output. A second variable delay means for delaying the reference NTSC signal based on the phase comparison output of the first phase comparison means in the time base collector circuit for outputting the video signal phase-controlled by the first variable phase control means; Reference N delayed by variable delay means
Second variable phase control means for controlling the phase of the TSC signal,
A second phase comparison between the reference NTSC signal and the output of the second variable phase control means and a phase comparison output as a signal for phase control by the first and second variable phase control means.
A time base collector circuit comprising a phase comparison means.