KR950004131B1 - Sub sampling control apparatus - Google Patents

Abstract

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Description

Subsampling Control Device Using 2 Channel Multiplexer

1 is an explanatory diagram showing a 4: 2: 2 sampling ratio of a luminance signal component and a chrominance signal component of a video signal;

2 is a block diagram showing a conventional subsampling control device.

3 is a block diagram showing a subsampling control apparatus according to the present invention.

4 is a waveform diagram of a control signal output through the pulse generator of the present invention.

FIG. 5 is a diagram for explaining a switching operation of the first and second multiplexers shown in FIG.

* Explanation of symbols for Chuo part of drawing

10: multiplexer 20: second multiplexer

30: A / D converter 40: pulse generator

50: first divider 60: second divider

H, L: Movable terminal A: Fixed terminal

S1, S2, S3: Control Signal

The present invention relates to a sub-sampling control apparatus for compressing and transmitting a luminance signal component and a chrominance signal component of an analog video signal into a digital video signal in a digital video medium, and in particular, using a sub-channel multiplexer. A sampling control device.

As is well known, the sampling frequency of the luminance signal for digitally encoding the luminance signal (Y) and the color difference signal (C _R , C _B ) in the CCIR 601 Recommendation on the coding parameters of the digital video media. It is recommended that the sampling frequency of 13.5MHz and each color difference signal be 6.75MHz.

In this way, the sampling frequency of the luminance signal is doubled with respect to the sampling frequency of the color difference signal, which is called a 4: 2: 2 sampling ratio. The components of the image signal sampled at the above ratio are shown in FIG.

Meanwhile, conventionally, two methods are used to subsample the luminance signal Y and the color difference signals C _R and C _B at a 4: 2: 2 ratio.

In the first method, A / D conversion of both the luminance signal (Y) and the color difference signal (C _R , C _B ) to 13.5 MHz, and then digitally filter only the color difference signals (C _R , C _B ) This is how we make the ratio 2: 2.

That is, similarly to the luminance signal (Y) color difference signals (C _R, C _B) at the same time, then after A / D conversion at a rate of 13.5MHz takes a first luminance signal (Y _1), the first color difference signal (C _R1), and After taking the second color difference signal C _R2 divided by 2, that is, the average color difference signal C _R , and again taking the second luminance signal Y ₂ , the first color difference signal C _B1 and the second color difference signal Cm In this method, three A / D converters are required for each signal, and hardware for calculating the average value of each color difference signal (C _R , C _B ) You will need software.

As a second method, as shown in FIG. 2, the four-channel multiplexer 70 and the timing adjusting circuit 80 are used. The multiplexer 70 has a luminance signal Y and a color difference signal at three input terminals. C _R , C _B ) and a method of sequentially outputting the signals programmed to the timing adjusting circuit 80 through the output terminals SO ₁ and SO _{2. In} this case, the luminance signal Y and the color difference Signals C _R and C _B extend the multiplexer 70 to Y, C _R , Y, C _B , Y, C _R , Y,... Will be output in the order of.

However, this also requires an additional configuration of the timing adjustment circuit, and requires software for outputting the control signal through the output terminal of the adjustment circuit.

The present invention has been made in view of the above circumstances, and in the process of changing the luminance component and the chrominance component of an analog video signal into a digital signal, switching dimming of a two-channel multiplexer is performed by using a sampling frequency generated by a pulse generator. It enables 4: 2: 2 subsampling without the need for timing control circuitry, resulting in reduced software loads and lower production costs.

A subsampling control apparatus using a two-channel multiplexer according to the present invention for realizing the above object receives an analog image signal and converts the luminance signal component (Y) and the chrominance signal component (U, V) into a digital image signal. 1. A subsampling control apparatus for compressing and transmitting data in a subsampling control apparatus, comprising: pulse generating means for generating and outputting a square wave pulse signal of a predetermined period; A second divider for dividing and outputting the output signal of the first divider by two, and selectively switching the respective color difference signal components U and V according to a predetermined control signal outputted from the second divider The output signal of the first switching means and the luminance signal component (Y) on the basis of the first switching means for outputting and the predetermined switching control signal output from the first divider. And a second switching means for switching and outputting the signal, and an A / D converter for converting the analog signal output from the second switching means into a digital signal based on the square wave pulse output from the pulse generating means. It features.

On the other hand, as shown in FIG. 4, according to the present invention having the above configuration, the pulse signal S ₃ output from the pulse generator 40 is a control signal for controlling the A / D converter 30. The pulse signal S ₂ outputted through the first divider 50 is a control signal for controlling the second multiplexer 20 and is a pulse signal through the second divider 60. S ₁ may act as a control signal for controlling the first multiplexer 10.

The operation of the apparatus according to the present invention will be described in more detail with reference to the accompanying drawings.

When the first pulse signal 40 is output from the pulse generator 40, the control signal S3 for controlling the A / D converter 30 is in a "high" level state, and is provided through the first divider 50. The output control signal S2 also becomes a "high" level state.

On the other hand, the switching operation of the first and second multiplexers 10 and 20 is a terminal H when the control signals S1 and S2 are high level with respect to the switching control signals S1 and S2, as shown in FIG. At the low level, the switch is connected to the L terminal.

Therefore, the color difference signal U is output through the first multiplexer 10, but since the switch inside the second multiplexer 20 is connected to the movable terminal L, the color difference signal U is not output and the luminance is reduced. Only the signal Y is output to the A / D converter 30 through the movable terminal H and the fixed terminal A of the second multiplexer 20.

That is, the first pulse signal (1) of the pulse generator 40 outputs the luminance signal (Y).

The control signal S ₃ for controlling the A / D converter 30 to which the second pulse signal ② is output is in a "high" level state, and the control signal S ₂ through the first divider 50 is As shown in the waveform shown in FIG. 4, the signal is in the "low" level state, and the control signal S ₄ through the second divider 60 is in the "high" level state.

Therefore, the color difference signal U is output to the movable terminal L of the second multiplexer 20 through the movable terminal and the fixed terminal A of the first multiplexer 10, and the control signal through the first divider 50. Since S ₂ is in the "low" level state, it is switched to the movable terminal L of the second multiplexer 20 and output to the A / D converter 30.

That is, the second pulse signal 2 of the pulse generator 40 outputs the color difference signal U.

When the third pulse signal ③ is outputted, the control signal S3 is in the "high" level state, the control signal S2 passing through the first divider 50 is in the "high" level state, and the control signal S ₁ ) becomes the "low" level state.

Therefore, the color difference signal V is output to the movable terminal L of the second multiplexer 20 through the movable terminal L and the fixed terminal A of the first multiplexer 10, but Since the control signal S ₂ is in the "high" level state, the control signal S ₂ is not opened and output, and the luminance signal Y is output to the A / D converter.

That is, the third pulse signal ③ outputs the luminance signal Y.

When the fourth pulse signal ④ is output, the control signals S _{1 to} S ₃ are in the "low" level and the "high" level state, which outputs the color difference signal V to the A / D converter 30.

When the fifth pulse signal (⑤) is output, the luminance signal (Y) is output to the A / D converter 30 through the above-described process, and when the sixth pulse signal (⑥) is output, the color difference signal (U) is output. Is output to the A / D converter 30.

Therefore, when the pulse signal is sequentially applied by the pulse generator 40, the output of the second multiplexer 20 is output in the order of Y, U, Y, V, Y, U, Y, V, ... When the converter 30 converts the analog signal into a digital signal, a signal subsampled at a sampling ratio of 4: 2: 2 is obtained.

As described above, according to the present invention, a separate timing generation circuit is not added by using a two-channel multiplexer and controlling the multiplexer using a two-division signal and a four-division timing signal of a sampling frequency output from a pulse generator. It is possible to realize a subsampling control device using a two-channel multiplexer, which can be simply subsampled at a 4: 2: 2 sampling ratio without the necessity.

Claims (1)

A subsampling control device for receiving an analog video signal and compressing and transmitting the luminance signal component (Y) and the chrominance signal component (U, V) of the signal as a digital video signal. A pulse generating means for generating and outputting a signal, a first divider for dividing and outputting a signal output from the pulse generating means, a second divider for dividing and outputting an output signal of the first divider, and First switching means for selectively switching each of the input color difference signal components U and V according to a predetermined control signal output from the second divider, and a predetermined switching output from the first divider; Second switching means for selectively switching and outputting the output signal of the first switching means and the luminance signal component Y based on a control signal, and an analog output from the second switching means. And an A / D converter for converting a signal into a digital signal based on a square wave pulse output from the pulse generator.