JP2000201357A - Luminance signal and color signal separating circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a luminance signal and color signal separating circuit by which no horizontal dot is generated even when a change of a color signal exists in the vertical direction. SOLUTION: The luminance signal and color signal separating circuit is provided with a color extracting means 101 to switch passing bands of a color signal to be extracted from a composite video signal, a luminance extracting means 701 to obtain luminance output by subtracting color output from the composite video signal, a horizontal dot frequency component detecting means 301 to extract horizontal dot components from a horizontal dot frequency area near one quarter of line correlation frequency from the composite video signal and near color carrier frequency, a reference signal extracting means 501 to detect reference components of specified frequency of the composite video signal and a comparison means 601 to obtain compared output between the horizontal dot components and the reference components and the passing band of the color extracting means is switched so that the horizontal dot frequency area is included in the passing band when a state that many horizontal dot components exist is shown by the compared output.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a luminance signal chrominance signal separation circuit which does not generate horizontal dot disturbance when separating a luminance signal and a chrominance signal from a composite television signal.

[0002]

2. Description of the Related Art FIG. 13 is a block diagram of a conventional luminance signal / chrominance signal separation circuit usually used for a VTR or a TV receiver. In FIG. 13, 1 is an input terminal,
2, 3 are output terminals, 5 is an A / D converter, 100 is a color signal extraction filter, 700 is a luminance signal extraction filter, and 6, 7 are D / A converters. The composite video signal V input from the input terminal 1 is converted from an analog signal to a digital signal v by the A / D converter 5 and supplied to the color signal extraction filter 100 and the luminance signal extraction filter 700. The output c of the color signal extraction filter 100 is
00 and the D / A converter 6. The signal c is converted from a digital signal to an analog signal by the D / A converter 6 and output from the output terminal 2 as a color signal C. The output y of the luminance signal extraction filter 700 is converted from a digital signal into an analog signal by the D / A converter 7, and is output from the output terminal 3 as a luminance signal Y.

FIG. 14 is a diagram showing the color signal extraction filter 100 in FIG. In the figure, a color signal extraction filter 100 is a vertical bandpass filter 120 including one horizontal line delay unit 110 and a bandpass filter 121.
And a horizontal bandpass filter 150 including a delay device 140a, a delay device 140b, and a bandpass filter 151.
It is composed of The input composite video signal is provided to the band pass filter 121 and the one horizontal line delay unit 110. The output of one horizontal line delay unit 110 is provided to bandpass filter 121. Bandpass filter 1
The output of 21 is a band pass filter 151 and a delay unit 14.
0a. The output of the delay unit 140a is provided to the band-pass filter 151 and the delay unit 140b. The output of delay device 140b is provided to bandpass filter 151. The output of the band pass filter 151 becomes the output c of the color signal extraction filter 100. Note that the delay device 140
a and the delay unit 140b each delay two pixels.

FIG. 15 is a diagram showing a luminance signal extraction filter 700 in FIG. In FIG.
Is a delay unit, and 770 is a subtractor. The c signal input to the luminance signal extraction filter 700 is provided to a subtractor 770. After the signal v is delayed by the delay unit 740, the subtractor 7
70. The output y of the subtractor 770 becomes the output y of the luminance signal extraction filter 700.

In this conventional luminance signal / color signal separation circuit,
For example, in the case of the NTSC broadcasting system, the horizontal line frequency is 15.734 kHz (hereinafter, referred to as "fl").
3.579545 MHz (hereinafter, referred to as "1 l") for each horizontal line (approximately 63.5 μs).
The burst and color signal of “fsc” are inverted and transmitted. This is because fsc = 227.5fh. Utilizing this property, it is used as a filter for separating a luminance signal and a chrominance signal.

Next, the operation will be described. The output signal v of the A / D converter 5 is first input to the vertical bandpass filter 120 including the 11 (L) delay unit 110 and the bandpass filter 121 in the color signal extraction filter 100. This vertical bandpass filter 12
At 0, the frequency fsc of the signal v is doubled by the 11 delay unit 110 and the band-pass filter 121, and is doubled even if the frequency is an integer multiple of fl from the fsc. However, as in the case of vertical stripes, the frequency has a minimum value when the frequency is an integral multiple of fl (ell), and has a frequency characteristic similar to the shape of a comb tooth. Since the NTSC broadcasting system uses frequency interleaving when multiplexing a luminance signal and a chrominance signal, a chrominance signal spectrum is distributed between frequency spectra standing for every fl (ell). Therefore, if a filter having a comb-like frequency characteristic is used, it is possible to extract a luminance signal spectrum or a color signal spectrum that stands for each fl (ell). In addition,
This vertical bandpass filter 120 has the following transfer function. VB (z) = (1/2) (1-1z- ^l )

Next, an output signal of the vertical band-pass filter 120 is supplied to a horizontal band-pass filter 150 composed of delay units 140a and 140b and a band-pass filter 151.
Is input to The horizontal band-pass filter 150 has a characteristic of passing a frequency band in which a color signal exists (for example, 3.58 MHz ± 500 kHz in the NTSC system), and has the following transfer function. HB (z) = (1/4) (-1 + 2z ^-2 -z ^-4 )

The horizontal band-pass filter 150 sets a band having a comb-like frequency characteristic.

The delay unit 740 constituting the luminance signal extraction filter 700 is a circuit for compensating for the propagation delay of the vertical band-pass filter 120 and the horizontal band-pass filter 150, and the subtractor 770 uses the output of the delay unit 740 , A y signal is generated by subtracting the c signal output from the color signal extraction filter 100.

The color signal extraction filter 100 is generally called a comb filter because of the above-mentioned properties, but is also called a horizontal / vertical bandpass filter (HVB) since both horizontal and vertical bandpass filters are connected in cascade. .

FIG. 16 shows an extraction band of a color signal extraction filter 100 which is a horizontal / vertical band pass filter (HVB). Here, the horizontal high-frequency component Y _h of the luminance signal
Because but not extracted as the color signal, the cross color is not generated even when processing a signal including a Y _h. In addition,
The cross color is a disturbing component in which a luminance signal becomes a rainbow-like color signal when there are fsc vertical stripes as shown in FIG. 17, for example. Also, if there is a horizontal high frequency component C _h color signals, for which a not extracted as a color signal in the color signal extraction filter 100, the color signal is crowded leaked to the luminance signal, dot interference is generated. This is a vertical dot when there is a color transient in the horizontal direction as shown in FIG. 17 (when changing from green to magenta as shown in FIG. 17). If there is a vertical high frequency component _Cv of the color signal (there is a change in the color signal in the vertical direction), this is also the color signal extraction filter 10
In the case of 0, since the color signal is not extracted as a color signal, the color signal leaks into the luminance signal and dot interference occurs. This is a horizontal dot as shown in FIG. 17, for example.

FIG. 18 shows various signal components on a two-dimensional frequency plane, and the characteristics of each region are described below. v _a : a region where _a composite video signal is mainly distributed Y _a : a region where _a luminance signal is mainly distributed Y ₀ : a region where a low frequency component of the luminance signal is distributed Y _h : a region where a horizontal high frequency component of the luminance signal is distributed Cause of cross color C _a : area where color signal is mainly distributed C ₀ : area where low frequency component of color signal is distributed _Ch : area where horizontal high frequency component of color signal is distributed and there is a color transient in the horizontal direction The cause of the vertical dot _Cv : The cause of the horizontal dot in the area where the vertical high-frequency component of the color signal is distributed _vb : The area where the band of the composite video signal is vertically limited _Hb : The band of the composite video signal is horizontally limited region

[0013]

Since the conventional luminance signal / chrominance signal separation circuit is constructed as described above, there is a problem that horizontal dots are generated when the color signal changes between lines. .

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and has as its object to realize a luminance signal color signal separation circuit that does not generate horizontal dots even when color signals change between lines. I do.

[0015]

A luminance signal / chrominance signal separation circuit according to the present invention extracts a color signal component from an input composite video signal, and switches a pass band of the extracted color signal component to convert a color signal. A color signal extracting means for outputting, a luminance signal extracting means for subtracting the color signal output from the composite video signal to obtain a luminance signal output, and A nonlinear horizontal dot frequency component detecting means for detecting a horizontal dot frequency component in a frequency region near the carrier frequency; a reference signal extracting means for extracting a component of a predetermined frequency region of the composite video signal and outputting it as a reference signal; Comparing means for comparing the output signal of the dot frequency component detecting means with the output signal of the reference signal extracting means and outputting a comparison result; As horizontal dot component of the color signal output is outputted from the extracting means is reduced is obtained and means for switching the pass band of the color signal of the color signal extracting means.

The reference signal extracting means is constituted by a delay means for giving the same delay time as the horizontal dot frequency component detecting means.

The reference signal extracting means adds the same delay time as that of the horizontal dot frequency component detecting means to a signal of a band wider than the color signal low frequency area in the input composite video signal.

The reference signal extracting means adds the same delay time as that of the horizontal dot frequency component detecting means to a signal near one half of the line correlation frequency in the input composite video signal.

The reference signal extracting means adds the same delay time as the horizontal dot frequency component detecting means to a signal near the color carrier frequency in the input composite video signal.

The reference signal extracting means adds the same delay time as the horizontal dot frequency component detecting means to the luminance component signal of the input composite video signal.

The comparing means weights the signals to be compared.

Further, the line correlation frequency is set as a horizontal scanning frequency so as to correspond to an NTSC composite video signal.

Further, the line correlation frequency is set to one half of the horizontal scanning frequency so as to correspond to the PAL composite video signal.

The nonlinear horizontal dot frequency component detecting means converts the signal near the half of the line correlation frequency and the signal near the line frequency 0 cph into absolute values, and calculates the minimum value of these two absolute signals. This minimum value is used as the center frequency of the color carrier frequency signal to limit the band in the horizontal direction.

The color signal extracting means comprises a vertical band-pass filter having a line delay, a horizontal band-pass filter having a delay, and a switch circuit.

[0026]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be specifically described with reference to the drawings showing the embodiments. Embodiment 1 FIG. FIG. 1 is a block diagram showing a configuration of a luminance signal color signal separation circuit according to Embodiment 1 of the present invention. In the figure, 1 is an input terminal, 2 and 3 are output terminals, 5 is an A / D converter, 101 is a color signal extraction filter, 301 is a horizontal dot frequency component detection filter, 501 is a reference signal extractor, and 601 is a comparator. , 701 is a luminance signal extraction filter, and 6, 7 are D / A converters.

FIG. 2 shows the color signal extraction filter 10 shown in FIG.
FIG. 1 is a block diagram showing one configuration example. In the figure,
122 is a vertical bandpass filter, 111 is one horizontal line delay, 123 is a bandpass filter, 152 is a horizontal bandpass filter, 141a and 141b are delays, 1
53 is a bandpass filter, and 102 is a switch circuit.

FIG. 3 is a block diagram showing an example of the configuration of the horizontal dot frequency component detection filter 301 in FIG. In the figure, reference numeral 351 denotes a horizontal band-pass filter;
a, 341b are delay devices, 352 is a bandpass filter,
321a is a vertical bandpass filter, 311 is one horizontal line delay device, 322a is a bandpass filter, 321b
Is a vertical low-pass filter, 322b is a low-pass filter, 302a and 302b are absolute value circuits, and 303 is a minimum value circuit.

FIG. 4 is a block diagram showing a configuration example of the reference signal extractor 501 in FIG. In the figure, 54
0 is a delay unit.

FIG. 5 is a block diagram showing a configuration example of the comparator 601 in FIG. In the figure, 602 is an absolute value circuit, and 670 is a subtractor.

FIG. 6 shows the luminance signal extraction filter 7 in FIG.
FIG. 1 is a block diagram showing an example of the configuration of No. 01. In the figure,
740 is a delay unit, and 770 is a subtractor.

The operation of the luminance signal / chrominance signal separation circuit according to the first embodiment will be described with reference to FIGS. As shown in FIG. 1, a composite video signal V input from an input terminal 1 is converted from an analog signal into a digital signal v by an A / D converter 5, and the color signal extraction filter 101
The luminance signal extraction filter 701, the horizontal dot frequency component detection filter 301, and the reference signal extractor 501 are provided. Output channel of horizontal dot frequency component detection filter 301
And the output re of the reference signal extractor 501 is both the comparator 6
01 is given. The output V / VH of the comparator 601 is provided to the color signal extraction filter 101 as a control signal.
The output c of the color signal extraction filter 101 is provided to the luminance signal extraction filter 701 and the D / A converter 6. The digital signal c is converted into an analog signal C by the D / A converter 6 and output from the output terminal 2. Luminance signal extraction filter 7
The output y of 01 is converted from a digital signal y to an analog signal Y by the D / A converter 7 and output from the output terminal 3.

As shown in FIG. 2, the color signal extraction filter 1
The composite video signal v input to 01 and the signal obtained by delaying the composite video signal v by one horizontal line delay 111 are supplied to a band-pass filter 123. The one horizontal line delay unit 111 and the bandpass filter 123 constitute a vertical bandpass filter (VB) 122, and fl (ell)
/ 2 as the center frequency.

The output of the vertical bandpass filter 122 is
It is provided to the switch circuit 102. Switch circuit 102
Is supplied with a VB output and an input composite video signal v. One of these signals is selected by the control signal H / VH. The output of the switch circuit 102 and the signal obtained by sequentially delaying this signal by the delay units 141a and 141b are supplied to the band-pass filter 153. The delay unit 141a, the delay unit 141b, and the band-pass filter 153 are a horizontal band-pass filter (HB).
152 and passes the signal with fsc as the center frequency. That is, the output c of the color signal extraction filter 101
The output of the horizontal band-pass filter (HB) 152 by the operation of the switch circuit 102 and the control signal H / VH,
By connecting the vertical band-pass filter (VB) 122 and the horizontal band-pass filter (HB) 152 vertically, one of the signals output from the horizontal-vertical band-pass filter (HVB) is selected. The VB 122 has the following transfer function. VB (z) = (1/2) (1-z ^-l )

The HB 152 has the following transfer function. HB (z) = (1/4) (-1 + 2z ^-2 -z ^-4 )

Therefore, the horizontal and vertical bandpass filters (H
VB) has the following transfer function: HVB (z) = (1/8) (1-z ^-l ) (-1 + 2z ^-2 -z ^-4 )

As shown in FIG. 3, in the horizontal dot frequency component detection filter 301, the input composite video signal v
The signal obtained by sequentially delaying the signal v by the delay unit 341a and the delay unit 341b is applied to the band-pass filter 35.
2 given. The delay units 341a and 341
b, the band pass filter 352 constitutes a horizontal band pass filter 351 and passes the signal with fsc as the center frequency. The output of the horizontal bandpass filter 351 and the signal obtained by delaying this signal by one horizontal line delay 311 are provided to the bandpass filter 322a.

The one horizontal line delay unit 311 and the band pass filter 322a are connected to a vertical band pass filter 321a.
, And the signal is passed with fl (ell) / 2 as the center frequency. Further, the horizontal band pass filters 351 and 1
The signal delayed by the horizontal line delay 311 is provided to the low-pass filter 322b. The one horizontal line delay unit 311 and the low-pass filter 322b constitute a vertical low-pass filter 321b and have a cut-off characteristic of fl (ell) / 2. The output of the vertical band-pass filter 321a and the output of the vertical low-pass filter 321b are supplied to absolute value circuits 302a and 302b, respectively, are converted into absolute values, and then supplied to the minimum value circuit 303. Minimum value circuit 3
03 is output from the horizontal dot frequency component detection filter 301.
Output signal cv.

The composite video signal v input to the reference signal extractor 501 is applied to a delay unit 540 as shown in FIG. 4 and is delayed by two pixel periods. The output of the delay unit 540 becomes the output signal re of the reference signal extractor 501.

The signal re input to the comparator 601
Is given to the absolute value circuit 602 as shown in FIG.
The output of the absolute value circuit 602 and the input signal cv are subtracted by a subtractor 67.
0, and the output of the subtractor 670 is
01 output signal H / VH. The signal H / VH is a comparison result between the output signal cv of the horizontal dot frequency component detection filter 301 and the output signal re of the reference signal extractor 501, and is provided to the color signal extraction filter 101 to switch the switch circuit 102. Becomes

The composite video signal v input to the luminance signal extraction filter 701 is supplied to the delay unit 74 as shown in FIG.
0 and delayed for two pixel periods. The output of the delay unit 740 is provided to a subtractor 770, which subtracts the color signal c, which is the other input signal. The output of the subtractor 770 becomes the output signal y of the luminance signal extraction filter 701.

An output signal cv lateral dot frequency component detection filter 301 is distributed as C _v in the two-dimensional frequency domain shown in FIG. 18. Also, the reference signal extractor 50
1 of the output signal re is distributed as v _a shown in FIG. 18. That is, the comparator 601 converts the signal cv, which is an extracted component from the region where the vertical high frequency component of the color signal is distributed, into
This is to be compared with the reference signal re, which is a composite video signal. When cv is larger than re, there is a change in the color signal in the vertical direction. When the color signal is extracted by HVB, the image is determined to be an image in which horizontal dots are generated, and a switch is performed by the control signal H / VH to select VB. The circuit 102 is switched.

FIG. 7 is a diagram showing the frequency domain of the extracted signal component of each filter in the horizontal dot frequency component detection filter 301. The minimum value of the absolute value component of each of the vertical band-pass filter (VB) 321a having one horizontal line delay unit 311 and the vertical low-pass filter 321b is the frequency component indicated by the hatched portion in FIG. That is, a signal component centered on fl (ell) / 4 can be extracted. When a signal component centered at fl (ell) / 4 is extracted by a linear filter and used, 1
Where two horizontal line delay units are required, the first embodiment can be realized with one horizontal line delay unit.

As described above, one horizontal line delay unit 311 of the horizontal dot frequency component detection filter 301 can be realized by one line, and as shown in FIG.
Since the vertical bandpass filter 122 in 1 is also constituted by one horizontal line delay unit and one line, the memory of the entire system can be realized at low cost.

As described above, the dot interference removal circuit according to the first embodiment includes an A / D converter, a color signal extraction filter, a horizontal dot frequency component detection filter, a reference signal extractor, a comparator, , Luminance signal extraction filter and D / A
A horizontal dot frequency component detection filter for extracting a horizontal high-frequency component of a color signal, a reference signal extractor for extracting mainly a composite video signal, a comparator for comparing this, and a color signal extraction filter. By switching the middle filter, the luminance signal and the color signal in which the horizontal dots are suppressed can be separated.

Incidentally, one horizontal line delay device 111, 31
1, 511, 513, and 516 are NTSCs in which color signals are inverted for each line by delaying one line.
Adapt to the signal. In this case, if the frequency at which the phase of the color signal is inverted, that is, the frequency at which the line has an inverse correlation is the line correlation frequency, this is the same as the horizontal scanning frequency.

Embodiment 2 FIG. 8 is a block diagram showing a reference signal extractor 501b in a luminance signal / chrominance signal separation circuit according to Embodiment 2 of the present invention. In the figure, 52
0 is a vertical band pass filter, 511 is a 1 horizontal line delay unit, 521 is a band pass filter, 553 is a horizontal band pass filter, 541 is a delay unit, 554 is a band pass filter, and 542 is a delay unit.

The composite video signal v input to the reference signal extractor 501b and this signal v
1 is converted to a band-pass filter 521
Given to. The one horizontal line delay unit 511 and the band-pass filter 521 constitute a vertical band-pass filter 520, which passes fl (ell) / 2 as a center frequency. The output of the vertical band-pass filter 520 and the signal obtained by delaying this signal by the delay unit 541 are provided to the band-pass filter 554. The delay unit 541 and the band pass filter 554 are connected to the horizontal band pass filter 55.
3 and passes the signal with fsc as the center frequency. The output of the horizontal band-pass filter 553 is
2 and the output signal re of the reference signal extractor 501b
Becomes

[0049] The above operation, C _a shows the output signal re of the reference signal extractor 501 in the first embodiment in FIG. 18
It is extracted as follows. That is, the comparator 6 in FIG.
In the case of 01, the signal cv, which is an extracted component from the area where the vertical high-frequency component of the color signal is distributed, is compared with the reference signal re, which is the entire band of the color signal. That is, comparison is made between frequency regions where color signals are present, and highly accurate detection is possible from an image in which color signals are mixed. When cv is larger than re, there is a change in the vertical direction, and when a color signal is extracted by HVB, it is determined that the image has horizontal dots.
Switch circuit 1 by control signal H / VH to select HB
By switching 02 (selecting the input v signal), it is possible to separate the luminance signal color signal in which the horizontal dots are suppressed.

Embodiment 3 FIG. 9 is a block diagram showing a reference signal extractor 501c in a luminance signal / chrominance signal separation circuit according to Embodiment 3 of the present invention. In the figure, 5
Reference numeral 22 denotes a vertical band-pass filter, 513 denotes a horizontal line delay unit, 523 denotes a band-pass filter, and 514 denotes a delay unit.

The composite video signal v input to the reference signal extractor 501c and this signal v
3 is delayed by the band-pass filter 523.
Given to. The one horizontal line delay unit 513 and the band-pass filter 523 constitute a vertical band-pass filter 522, and allow fl (ell) / 2 as a center frequency. The output of the vertical band-pass filter 522 is delayed by the delay unit 514 and becomes the output signal re of the reference signal extractor 501c. The delay unit 514 compensates for the delay time of the horizontal dot frequency component detection filter 301.

[0052] The above operation is obtained by extracting the output signal re of the reference signal extractor 501 in the first embodiment as v _b shown in FIG. 18. That is, the comparator 60 of FIG.
In 1, the signal cv, which is an extracted component from the region where the vertical high-frequency components of the color signal are distributed, is compared with the reference signal re, which is a band component having a center frequency of fl (ell) / 2. When cv is larger than re, there is a change in the color signal in the vertical direction. When the color signal is extracted by HVB, the image is determined to be an image in which horizontal dots are generated, and a switch circuit is selected by the control signal H / VH so as to select HB. By switching 102, a luminance signal and a color signal in which horizontal dots are suppressed can be separated. Further, since the configuration of the vertical bandpass filter 522 and the configuration of the vertical bandpass filter 122 are the same, it is also possible to use the same.

Embodiment 4 FIG. 10 is a block diagram showing a reference signal extractor 501d in a luminance signal / chrominance signal separation circuit according to Embodiment 4 of the present invention. In the figure,
555 is a horizontal band pass filter, 544a, 544b
Is a delay unit, and 556 is a bandpass filter.

The composite video signal v input to the reference signal extractor 501d and the signal obtained by sequentially delaying this composite signal v by the delay units 544a and 544b are applied to the band-pass filter 556. The delay unit 544a and the delay unit 54
4b, the band-pass filter 556 constitutes a horizontal band-pass filter 555, and passes with fsc as the center frequency. The output of the horizontal bandpass filter 555 is the output signal re of the reference signal extractor 501d.

The above operation is such that the output signal re of the reference signal extractor 501 in the first embodiment is extracted like Hb shown in FIG. That is, the comparator 60 of FIG.
In 1, the signal cv, which is an extracted component from the region where the vertical high-frequency component of the color signal is distributed, is compared with the reference signal re, which is a band component having a center frequency of fsc. c
When v is larger than re, there is a change in the color signal in the vertical direction. When the color signal is extracted by HVB, it is determined that the image has horizontal dots, and the control signal H is selected to select HB.
By switching the switch circuit 102 at / VH, it is possible to separate a luminance signal and a color signal in which horizontal dots are suppressed.

Embodiment 5 FIG. 11 is a block diagram showing a reference signal extractor 501e in the luminance signal / chrominance signal separation circuit according to the fifth embodiment of the present invention. In the figure,
526 is a vertical low-pass filter, 516 is one horizontal line delay, 527 is a low-pass filter, 545 is a delay,
528 is a horizontal low-pass filter, 546a and 546b are delay units, 529 is a low-pass filter, and 570 is an adder.

The composite video signal v input to the reference signal extractor 501e is input to one horizontal line delay 516.
The composite video signal v and the signal obtained by delaying the composite video signal v by the one horizontal line delay unit 516 are combined with a low-pass filter 527.
Given to. The one horizontal line delay unit 516 and the low-pass filter 527 constitute a vertical low-pass filter 526, and blocks fl (ell) / 2. On the other hand, the input composite video signal v and this signal v are
The signal sequentially delayed at 46b is applied to a low-pass filter 52.
9 given. These delay units 546a and 546
b, low-pass filter 529 is horizontal low-pass filter 5
28 to shut off fsc. Output of vertical low-pass filter 526 and horizontal low-pass filter 52
8 are added by an adder 570, and a reference signal extractor 5
01e is the output signal re.

The above operation is such that the output signal re of the reference signal extractor 501 in the first embodiment is extracted as shown by Ya in FIG. That is, the comparator 60 of FIG.
In 1, the signal cv, which is an extracted component from the region where the vertical high-frequency component of the color signal is distributed, is compared with the reference signal re, which is a component in which the luminance signal is mainly distributed. cv is r
When the value is larger than e, there is a color signal change in the vertical direction and HVB
When the color signal is extracted in step (1), the image is determined to be an image in which horizontal dots are generated, and the control signal H / VH is used to switch the switch circuit 102 so as to select HB. it can.

Embodiment 6 FIG. FIG. 12 shows a comparator 60 in the luminance signal / chrominance signal separation circuit according to the sixth embodiment of the present invention.
It is a block diagram showing 1b. In the figure, 602 is an absolute value circuit, 608 and 609 are multipliers, and 670 is a subtractor.

The signals cv and re input to the comparator 601b are multiplied by m and n by multipliers 608 and 609, respectively. The output of the multiplier 609 is supplied to the absolute value circuit 602, and the output of the absolute value circuit 602 is subtracted from the output of the multiplier 608 by the subtractor 670. The output of the subtracter 670 is used as the output signal H / VH of the comparator 601. Becomes The signal H / VH is provided to the color signal extraction filter 101 in FIG. 1 and serves as a control signal for switching the switch circuit 102.

In the above operation, the comparator 601 shown in FIG. 5 of the first embodiment is provided with multipliers 608 and 609. The output signal cv of the horizontal dot frequency component detection filter 301 and the reference signal extractor 501 Is weighted for each of the output signals re. By setting these values m times and n times, it is possible to determine the distribution of the amount of dot disturbance and cross color that occur.

Embodiment 7 The basic configuration of the seventh embodiment is the same as that of the first embodiment shown in FIG. 1, except that one horizontal line delay unit 111,
By setting all of the 311, 511, 513, and 516 to be two horizontal line delay units, it is possible to adapt to a PAL signal in which a color signal is inverted every two lines. In this case, assuming that the phase of the color signal is inverted, that is, the frequency at which the line has an inverse correlation is the line correlation frequency, this is the horizontal scanning frequency of 2
It will be a fraction. If one horizontal line delay unit of the horizontal dot frequency component detection filter 301 and the vertical band pass filter 122 of the color signal extraction filter 101 in the NTSC system is composed of two lines, in order to adopt a configuration adapted to the PAL signal. In the seventh embodiment, one horizontal line delay unit for four lines is required.
Since one horizontal line delay unit of the horizontal dot frequency component detection filter 301 and the vertical band pass filter 122 of the color signal extraction filter 101 in the NTSC system is composed of one line, even if the PAL signal is applied, One horizontal line delay unit for one line is sufficient, and the line memory for two lines can be reduced in comparison.

[0063]

Since the present invention is configured as described above, it has the following effects.

A color extracting means for taking a composite video signal as an input signal, extracting a color signal therefrom to obtain a color output, and switching a pass band, and a luminance for subtracting the color output from the composite video signal to obtain a luminance output Extracting means; non-linear horizontal dot frequency component detecting means for extracting a horizontal dot component from a horizontal dot frequency region near a quarter of a line correlation frequency and near a color carrier frequency from the composite video signal; Reference signal extracting means for detecting a reference component for extracting a predetermined frequency component; comparing means for obtaining a comparison output between the horizontal dot component and the reference component; Since there is provided means for switching so as to include the horizontal dot frequency region in the pass band of the color extracting means, luminance signal and color signal separation without horizontal dots can be realized. Further, an inexpensive luminance signal / color signal separation circuit with a small number of line delay units can be obtained.

Further, in addition to realizing the separation of the luminance signal and the color signal without horizontal dots, the reference signal extracting means is constituted by delay means for giving the same delay time as the horizontal dot frequency component detecting means. The means can be inexpensively constituted only by the delay device.

Further, in addition to realizing a luminance signal and a color signal separation without horizontal dots, the reference signal extracting means is used to convert a horizontal dot frequency component into a signal having a band wider than the color signal low frequency region in the input composite video signal. Since the color signals are compared with each other by providing the same delay time as that of the detection means, erroneous detection is reduced even in an image having a large degree of color signals.

Further, in addition to realizing a luminance signal and a chrominance signal separation without horizontal dots, the reference signal extracting means is used to reduce the half of the line correlation frequency of the input composite video signal.
Since the same delay time as that of the horizontal dot frequency component detecting means is added to the nearby signal, the filter used for detection and the filter used for color signal extraction can be used, and the scale of hardware can be reduced.

Further, in addition to realizing a luminance signal and a color signal separation without horizontal dots, the reference signal extracting means is used to convert the signal near the color carrier frequency of the input composite video signal into the same as the horizontal dot frequency component detecting means. Since the configuration is such that the delay time is given, the circuit scale can be reduced and the luminance signal and the chrominance signal without horizontal dots can be separated by sharing the delay unit of the reference signal extraction unit with other units.

Further, in addition to realizing a luminance signal and color signal separation without horizontal dots, the reference signal extracting means is used to add the same delay time as the horizontal dot frequency component detecting means to the luminance component signal of the input composite video signal. , The leakage from the luminance signal component is small, and
A luminance signal and a color signal without horizontal dots can be separated.

Further, since the comparing means is configured to weight the signals to be compared, it is possible to determine the distribution of the amount of dot disturbance and the amount of cross color that occur.

By setting the line correlation frequency to the horizontal scanning frequency, it is possible to cope with an NTSC composite video signal.

By setting the line correlation frequency to one half of the horizontal scanning frequency, it is possible to cope with a PAL composite video signal.

Further, the horizontal dot frequency component detection filter converts the signal near the half of the line correlation frequency and the signal near the line frequency 0 cph into absolute values, and takes the minimum value of the two absolute signals. Since this signal is band-limited in the horizontal direction with the color carrier frequency as the center frequency, horizontal dot frequency components can be detected by one horizontal line delay unit for one line.

Further, since the vertical band-pass filter of the color signal extraction filter is constituted by one horizontal line delay unit for one line, the memory scale of the whole system can be reduced, and it can be realized at low cost.

[Brief description of the drawings]

FIG. 1 is a block diagram of a luminance signal color signal separation circuit according to a first embodiment of the present invention.

FIG. 2 is a block diagram illustrating a color signal extraction filter according to the first embodiment.

FIG. 3 is a block diagram illustrating a horizontal dot frequency component detection filter according to the first embodiment.

FIG. 4 is a block diagram showing a reference signal extractor according to the first embodiment.

FIG. 5 is a block diagram showing a comparator according to the first embodiment.

FIG. 6 is a block diagram illustrating a luminance signal extraction filter according to the first embodiment.

FIG. 7 is a diagram illustrating a frequency region of an extracted signal component of a horizontal dot frequency component detection filter according to the first embodiment.

FIG. 8 is a block diagram showing a reference signal extractor according to Embodiment 2 of the present invention.

FIG. 9 is a block diagram showing a reference signal extractor according to Embodiment 3 of the present invention.

FIG. 10 is a block diagram showing a reference signal extractor according to Embodiment 4 of the present invention.

FIG. 11 is a block diagram showing a reference signal extractor according to Embodiment 5 of the present invention.

FIG. 12 is a block diagram showing a comparator according to a sixth embodiment of the present invention.

FIG. 13 is a block diagram of a conventional luminance signal / color signal separation circuit.

FIG. 14 is a block diagram showing a conventional color signal extraction filter.

FIG. 15 is a block diagram showing a conventional luminance signal extraction filter.

FIG. 16 is a conceptual diagram showing a color signal distribution in a two-dimensional frequency domain and an extraction band of a band-pass filter.

FIG. 17 is an explanatory diagram of interference that occurs on a screen.

FIG. 18 is a conceptual diagram showing a distribution of each signal in a two-dimensional frequency domain.

[Explanation of symbols]

1 input terminal, 2, 3 output terminal, 5 A / D converter, 6,
7 D / A converter, 101 color signal extraction filter, 10
2 switch circuits, 111, 311, 511, 513,
516,710 1 horizontal line delay, 122,321
a, 520, 522 vertical bandpass filter, 12
3,153,322a, 352,521,523,55
4,556 band pass filters, 141a, 141
b, 142, 341a, 341b, 514, 540, 5
41,542,544a, 544b, 545,546
a, 546b, 740 Delay device, 152, 351, 55
3,555 horizontal bandpass filter, 301 horizontal dot frequency component detection filter, 302a, 302b, 60
2 Absolute value circuit, 303 minimum value circuit, 501, 501
b, 501c, 501d, 501e Reference signal extractor,
321b, 526 vertical low-pass filter, 322b,
527 low-pass filter, 528 horizontal low-pass filter, 570 adder, 601, 601b comparator, 60
8,609 multiplier, 670,770 subtractor, 701
Luminance signal extraction filter.

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 5C066 AA03 BA02 CA09 DA05 DB06 DC02 DC06 DD08 EB11 EC14 EF02 GA01 GA05 GB14 HA01 JA03 JA06 KC02 KC04 KC06 KC11 KD07 KD08 KE02 KE16 KE19 KF03 KG05 KM11 LA02

Claims (11)

[Claims] 1. A color signal extracting means for extracting a color signal component from an input composite video signal, outputting a color signal by switching a pass band of the extracted color signal component, and outputting the color signal from the composite video signal. A luminance signal extracting means for subtracting an output to obtain a luminance signal output; Dot frequency component detection means, reference signal extraction means for extracting a component of the predetermined frequency region of the composite video signal and outputting it as a reference signal, output signal of the horizontal dot frequency component detection means and output of the reference signal extraction means A comparison means for comparing the signal with a signal to output a comparison result; and a horizontal dot component of a color signal output from the color signal extraction means based on the comparison result. Luminance-chrominance signal separation circuit which is characterized in that a means for switching the pass band of Kunar so the color signal of the color signal extracting means. 2. The luminance signal color signal separating circuit according to claim 1, wherein said reference signal extracting means comprises delay means for giving the same delay time as said horizontal dot frequency component detecting means. 3. The reference signal extracting means converts the input composite video signal into a signal having a band wider than a color signal low-frequency region,
2. The luminance signal / color signal separating circuit according to claim 1, wherein the same delay time as that of the horizontal dot frequency component detecting means is given. 4. The reference signal extracting means adds the same delay time as the horizontal dot frequency component detecting means to a signal near half of the line correlation frequency in the input composite video signal. The luminance signal / color signal separation circuit according to claim 1. 5. The reference signal extracting means according to claim 1, wherein the reference signal extracting means applies the same delay time as the horizontal dot frequency component detecting means to a signal near the color carrier frequency in the input composite video signal. Luminance signal color signal separation circuit. 6. The luminance signal according to claim 1, wherein the reference signal extracting means adds the same delay time as the horizontal dot frequency component detecting means to the luminance component signal of the input composite video signal. Color signal separation circuit. 7. The luminance signal color signal separation circuit according to claim 1, wherein the comparing means weights the signals to be compared. 8. The luminance signal color signal separation circuit according to claim 1, wherein the line correlation frequency is set as a horizontal scanning frequency so as to correspond to an NTSC composite video signal. 9. The method according to claim 1, wherein the line correlation frequency is set to 2 of the horizontal scanning frequency.
2. The luminance signal / chrominance signal separation circuit according to claim 1, wherein the luminance signal / chrominance signal separation circuit corresponds to a PAL composite video signal. 10. The non-linear horizontal dot frequency component detecting means converts a signal near a half of a line correlation frequency and a signal near a line frequency 0 cph to an absolute value, and calculates a minimum value of the two absolute signals. 2. The luminance signal color signal separation circuit according to claim 1, wherein the minimum value is band-limited in the horizontal direction as a center frequency of the color carrier frequency. 11. The color signal extracting means according to claim 1, wherein said color signal extracting means comprises a vertical band-pass filter having a line delay, a horizontal band-pass filter having a delay, and a switch circuit. A luminance signal / chrominance signal separation circuit according to claim 1.