JPH0378838B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a color demodulation circuit for a video reproducing device;
In particular, the present invention relates to a color demodulation circuit for a video playback device that plays back video using a color video signal based on the PAL (Phase Alternation Line) system.

PAL corresponding to the nth (n is a natural number) scanning line
The color video signal E _M n of the system is given in the following colors.

E _M n=Y+E _U sinωct + (-1) ⁿ E _V cosωct ...(1) ωc≒2πf _H (m-1/4) ...(2) Here, Y is the luminance signal, E _U and E _V indicate color difference signals B-Y and RY, respectively. Note that B and R indicate blue and red signals, respectively. Further, f _H is a horizontal scanning frequency, and m is a natural number. The coefficient (-1) ⁿ in equation (1) means phase inversion for each horizontal scanning line, and the E _V
The components are transmitted by balanced modulation of subcarrier signals of (-1) ⁿ cosωct having a phase difference of 180° for each horizontal scanning line. Therefore, the color burst signal is required to have information for inverting the phase of the _EV component subcarrier line by line on the image receiving side. Therefore, the color _burst signal is ±
The phase is switched to 135° for each line, and the phase-inverted version is sent out.

FIG. 1 shows a conventional color demodulation circuit in a device that reproduces video using such a PAL color video signal. In FIG. 1, a PAL color video signal is supplied to a bandpass filter 1. In FIG. The bandpass filter 1 is configured such that its passband is approximately equal to the frequency band of a carrier color signal included in a PAL color video signal. The carrier color signal component is extracted by this band filter 1 and supplied to a 1H (one horizontal scanning period) delay circuit 2, addition circuit 3, and subtraction circuit 4. The signal delay time in 1H delay circuit 2 is (π/2) × 1H
The time is set to be longer or shorter by (1/ωc). Therefore, in order to prevent the occurrence of vertical stripe interference, the phase of the subcarrier is shifted by π/2 between two consecutive scanning lines in the same field, so that the phase of the carrier color signal is exactly the same as the phase 1H before. However, the phase of the carrier color signal outputted from the 1H delay circuit 2 about 1H earlier almost matches the phase of the input signal. The output of the 1H delay circuit 2 is supplied to an addition circuit 3 and a subtraction circuit 4. In adder circuit 3, 1H
When the output of the delay circuit 2 is added to the carrier color signal, the _EV component of the carrier color signal is canceled and only the _EU component is output from the adder circuit 3. Further, in the subtraction circuit 4, for example, the output component of the 1H delay circuit 2 is subtracted from the carrier color signal, so that the E _U component of the carrier color signal is canceled and only the _EV component is output from the subtraction circuit 4. Ru. These adder circuits 3
The output of the subtracting circuit 4 is supplied to each of the doubler circuits 5 and 6, each of which is a full-wave rectifier circuit, for example, and also to the BY demodulator 7 and the RY demodulator 8, respectively. The _EU and _EV components whose frequencies have been doubled are output from the doubler circuits 5 and 6 and supplied to limiters 9 and 10, respectively. Limituta 9,1
0 is configured to amplify the signal obtained by limiting the amplitude of the input signal. These limiters 9, 10
E _U component and E _V whose frequency is doubled from each of
Signals having only the phase information of the components are outputted and both are supplied to the subtraction circuit 11. Subtraction circuit 1
1, by subtracting the limiter 10 from the output of the limiter 9, for example, a signal having a fundamental frequency component having a frequency twice the color carrier frequency is generated. The output of this subtraction circuit 11 is supplied to a subcarrier generator 12. The subcarrier generator 12 is, for example, an APC (Auto Phase
Control) method. That is, the subcarrier generator 12 includes, for example, a VCO (voltage controlled oscillator), and compares the output of the VCO with a signal obtained by dividing the output of the subtraction circuit 11 by two to determine the frequency and frequency between the two signals. The configuration is such that a color subcarrier signal of the _EV component is generated by obtaining a voltage corresponding to the phase difference and then supplying it to the control input terminal of the VCO. The color subcarrier signal outputted from the subcarrier generator 12 is phase-shifted by 90° by a 90° phase shifter 13 and supplied to the BY demodulator 7 as a subcarrier for detection. This color subcarrier signal is also supplied to a 180° phase shifter 14 that shifts the input phase by 180° and a PAL switch 15. PAL switch 15 is
The color subcarrier signal and the output of the 180° phase shifter 14 are alternately output every 1H.
The output of this PAL switch 15 is supplied to the RY demodulator 8 as a subcarrier signal for detection. Then, the BY signal and the RY signal are demodulated in each of the BY demodulator 7 and the RY demodulator 8 and output.

In the conventional color demodulation circuit as described above, components other than the carrier color signal components around the frequency of the carrier color signal are mixed into the output of the bandpass filter 1, so for example, luminance signals generated in response to characters or kimono patterns are mixed. A phenomenon in which short colored horizontal lines appear at the edges of vertical lines in the image obtained when a luminance signal containing many high frequency components near the frequency of the carrier color signal is present in the color video signal, giving the appearance of blurring. A so-called cross color will occur. Furthermore, since the conventional color demodulation circuit includes a doubling circuit and a limiter that process each of the E _V component and the E _U component, the circuit scale becomes large and the number of parts used is large. Due to the amplification effect, crosstalk between limiters 9 and 10 increases the amount of E _U component mixed into the _EV component or the amount of _EV component mixed into the _EU component, resulting in unstable operation. It was hot.

Therefore, an object of the present invention is to provide a video playback system that can demodulate color difference signals while reliably removing luminance signals and preventing problems such as cross color, and that also has stable operation and uses a small number of parts. An object of the present invention is to provide a color demodulation circuit for a device.

A color demodulation circuit for a video playback device according to the present invention is a color demodulation circuit for a video playback device that plays back video using a PAL color video signal in which one of the carrier color signals and a color burst signal are phase-inverted every horizontal scanning period. a signal delay means for delaying the luminance signal, the carrier color signal and the color burst signal by one horizontal scanning period; a subtraction means for outputting a difference between an input and an output of the signal delay means; a detection subcarrier signal generation means for generating a detection subcarrier signal synchronized with the output; and addition and subtraction between the output of the subtraction means and a signal obtained by delaying the output of the subtraction means by a predetermined period; The present invention includes an addition/subtraction means for separating and outputting each of the two carrier color signal components, and a demodulation means for demodulating a color difference signal from the output of the addition/subtraction means using the detection subcarrier signal.

Hereinafter, the present invention will be explained in detail with reference to FIG.

As shown in FIG. 2, a 1H delay circuit 2, an adder circuit 3,
The subtraction circuit 4, BY demodulator 7, and RY demodulator 8 are connected in the same way as in FIG. However, in this example, the PAL color video signal is supplied to a 1H delay circuit 16 and a subtraction circuit 17. The 1H delay circuit 16 is composed of, for example, a delay line whose signal delay time is equal to the time corresponding to 1H.
The output of this 1H delay circuit 16 is supplied to a subtraction circuit 17. In the subtraction circuit 17, for example, PAL
By subtracting the output of the 1H delay circuit 16 from the color video signal, it becomes a PAL color video signal.
Signals corresponding to the difference between the PAL color video signals 1H before are synthesized and supplied to the 1H delay circuit 2, addition circuit 3, subtraction circuit 4, and doubling circuit 18. The doubler circuit 18 is composed of, for example, a full-wave rectifier circuit. The output of this doubler circuit 18 is supplied to a limiter 19. The limiter 19 is configured to amplify the signal obtained by limiting the amplitude of the input. These doubler circuit 18 and limiter 19
As a result, a signal containing only phase information of a signal having a frequency twice the frequency of the output of the subtraction circuit 17 is obtained and supplied to the subcarrier generator 20. Subcarrier generator 20 is constructed similarly to subcarrier generator 12 in FIG. The output of this subcarrier generator 20 is shifted by a predetermined angle by a phase shifter 21 and then supplied to a BY demodulator 7 and an RY demodulator 8 as a subcarrier signal for detection. Then, the output of the B-Y demodulator 7 becomes a B-Y signal, and the output of the R-Y demodulator 8 and this R-Y
The output of the inverter 22, which inverts the phase of the output of the demodulator 8, is alternately outputted every 1H by the PAL switch 23 to become the RY signal.

In the above configuration, the output E _M of the 1H delay circuit 16
(n-1) is expressed by the following equation similarly to equation (1).

E _M (n-1) = Y + E _U sinωc (t-1/fH) + (-1) ⁿ E _V cosωc (t-1/f _H ) ...(3) Therefore, the output of the subtraction circuit 17 E _M n-E _M (n-
1) becomes as shown in the following equation.

E _M n−E _M (n−1)=E _U sinωct +(−1) ⁿ E _V cosωct −E _U sinωc(t−1/fH) −(−1) ⁿ E _V cosωc(t−1/fH )...(4) If we rearrange equation (4) using equation (2), we get the following equation.

E _M n-E _M (n-1) = {E _U + (-1) ⁿ E _V } √2 sin (ωct + π/4) ...(5) As is clear from equation (5), the output of the subtraction circuit 17 In this case, there is no luminance signal component, and the phases of the _EU and _EV components in the output of the subtraction circuit 17 match. Therefore, problems such as cross color do not occur, and unlike the conventional color demodulation circuit, two detection subcarrier signals having a phase difference of π/2 are generated, and the B-Y demodulator 7 and the R-Y There is no need to supply it to the demodulator 8, and both BY and RY signals can be obtained with a single subcarrier signal. Moreover, this single subcarrier signal is obtained by doubling the frequency of the output of the subtracting circuit 17 containing both _EU and _EV signal components, and then limiting the amplitude. You will be able to do so.

According to the present invention, the luminance signal can be reliably removed, the color difference signal can be demodulated by a single demodulation axis, and the doubler circuit and limiter for subcarrier signal generation can be integrated into a single unit. Therefore, it is possible to prevent problems such as cross collars from occurring, and the circuit configuration is simplified, so that the number of parts used can be reduced. In addition, since the limiter can be used as a single limiter, there is no mixing of other components into the E _U component or the _EV component due to crosstalk when two limiters are used, resulting in stable circuit operation. Interference with other circuits can be easily prevented, and the degree of freedom in circuit arrangement can be improved. Furthermore, as is clear from equation (5), the phases of the carrier components of the _EU and _EV components output from the addition circuit 3 and the subtraction circuit 4 match, so that they are mutually
There is no need to generate two detection subcarrier signals having a phase difference of 90°, and the circuit configuration can be simplified.

In the above embodiment, the R-Y signal was inverted after the synchronous detection, but the R-Y signal was inverted before the synchronous detection.
By inverting the subcarrier of the Y component, R
-Y signal may be inverted. Also,
In the subcarrier generator 20 in the above embodiment, a signal including a component whose phase is inverted every 1H and a vco
It is conceivable to omit the doubler circuit 18 by making it possible to control the frequency and phase of the output of the VCO by comparing the output of the VCO with the output of the VCO. Furthermore, in the subcarrier generator 20 in the above embodiment,
The phase of the output of vco is at the output of the subtraction circuit 17.
It is conceivable to omit the phase shifter 21 by matching the phase of the _EU component or the _EV component.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing a conventional color demodulation circuit, and FIG. 2 is a block diagram showing an embodiment of the present invention. Explanation of the symbols of the main parts, 2, 16... 1H delay circuit, 3... Addition circuit, 4, 17... Subtraction circuit,
7...B-Y demodulator, 8...R-Y demodulator, 18
...Double multiplier circuit, 19...Limiter, 20...Subcarrier generator, 21...Phase shifter, 22...Inverter, 23...PAL switch.

Claims (1)

[Claims] 1. A color demodulation circuit of a video reproducing device that reproduces a video based on a PAL color video signal in which one of the carrier color signals and the color burst signal is phase-inverted every horizontal scanning period, which signal delay means for delaying the color burst signal by one horizontal scanning period; subtraction means for outputting a difference between the input and output of the signal delay means; and detection for generating a detection subcarrier signal synchronized with the output of the subtraction means. subcarrier signal generation means, and a signal obtained by delaying the output of the subtraction means and the output of the subtraction means by a predetermined period, and performs addition and subtraction to separate and output each of the two carrier color signal components. 1. A color demodulation circuit for a video reproducing apparatus, comprising: an addition/subtraction means for performing the detection subcarrier signal; and a demodulation means for demodulating a color difference signal from the output of the addition/subtraction means using the detection subcarrier signal.