DE2438674A1 - CIRCUIT FOR DELIVERING A LUMINANCE AND CHROMINANCE SIGNAL FROM A COMPOSITE TELEVISION SIGNAL - Google Patents

Description

It 2988

SONY COEEOEATION
Tokyo, Japan

Circuit for supplying a luminance and chrominance signal from a composite television signal

The invention relates to a circuit for supplying a luminance and chrominance signal from a composite television signal (color image signal mixture) .

In television technology , it is desirable to eliminate mutual interference between the luminance and chrominance signals, which create so-called dot and cross color obstacles or interference. or, more precisely, a band attenuation filter is used} 'However, this proposed method is accompanied by an overshoot and image doubling caused by a phase shift of the luminance signal. In addition, it is quite difficult to provide such a band attenuation filter with a predetermined characteristic.

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Furthermore, a method has been proposed in which a luminance signal with a low frequency-amplitude profile · However, this procedure is not unaffected by the problem mentioned above.

The main object of the invention is to provide a circuit for supplying a luminance and chrominance signal from a composite television signal, i.e. a composite color image signal to deliver, which avoids the disadvantages of known circuits.

This object is achieved according to the invention by a bandpass filter with a pass band for a chrominance signal range of the composite signal, a comb filter which has a delay circuit with a delay time corresponding to a horizontal period, the filter being connected in series with the bandpass filter and a chrominance signal component from the composite video -Signal in connection with the bandpass filter extracts or supplies, by a delay device for delaying the composite signal by a predetermined time interval so that this composite signal is in phase with the chrominance signal component, and through a device for combining the chrominance signal component with an output signal the delay device with a predetermined polarity for the removal or delivery of a luiainance signal component,

According to a preferred embodiment of the invention it is provided that the device for combining the chrominance signal component with an output signal of the delay device is an amplifier for level control of the

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Chrominance signal component and phase reversal of this component and an adder for summing a Output signal of the amplifier to the output signal of the delay device.

The circuit according to the invention advantageously provides a luminance signal with a low or flat frequency-amplitude curve. It is also advantageous a phase shift of the luminance signal avoided, which the generation of an overshoot and a picture doubling would cause.

The composite signal is "in the circuit according to the invention advantageously by a predetermined time interval delayed to be in phase with the ear dominance signal component; then this PBAS signal with the chrominance signal component with a predetermined Polarity combined or summed to the luminance signal component to deliver or to extract from the color image signal mixture.

The composite color image signal is hereinafter referred to as the composite video signal designated.

In the following a preferred embodiment of the invention is explained in more detail with reference to drawings. It demonstrate:

1 shows a diagram for explaining the composite color image signal or the PBAS signal,

Pig. 2 a schematic representation of a known circuit,

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3 to 5 are graphic representations for explanation the circuit according to FIG. 2,

6 shows a circuit of an embodiment of the invention, and

7 to 10 are diagrams for explaining the circuit according to FIG. 6.

The following is a general description of the composite television signal given with reference to FIG.

According to Fig. 1, the composite color image signal consists of one Luminance signal Y and a chrominance signal C, which are produced by modulating a color auxiliary carrier signal with a frequency f is formed. As a result, obstacles are generated due to interference between these signals, which can be referred to as point obstacle and cross-color obstacle. The point obstacle or this disturbance appears on a screen by mixing the chrominance signal into the luminance signal while the latter Disturbance, i.e., the cross-color obstacle appears on the screen by the luminance signal in the chrominance signal is mixed. These "obstacles" or disturbances can be reduced to the extent that they appear on the screen due to the integral effect of the viewer by choosing the frequency f of the color auxiliary carrier signal in agreement imperceptibly with the theory of frequency interleaving will. However, these malfunctions cannot be completely eliminated. It is therefore desirable that these obstacles or disturbances are removed when the luminance and chrominance signals are separated or removed from the Color image signal composite or PBAS signal are removed,

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which is received or played back by a video tape recorder (VTE).

For this purpose, a method is proposed in which a comb filter consisting of a delay circuit for delaying a signal by one horizontal period is used. As shown in Fig., In this method in an adder 3 for generating a luminance signal Yy, a composite television signal, which is applied to an input terminal 1 at this point, and a composite television signal are combined by a delay circuit 2, the Delay circuit 2 delays a composite signal by one horizontal period; the composite signal from the delay circuit 2 leads by one horizontal period. The composite signal, which is received at this point in time from the input terminal 1 and the signal received by a phase reverser stage 4 - the phase reversal stage 4- reverses the phase of the composite signal of the delay circuit 2, are in an adder 5 to supply a chrominance signal Gy , combined.

The delay circuit 2, which delays the composite signal by one horizontal period, has essentially the same frequency response as a bandpass filter. The frequency response of the delay circuit 2 according to FIG. 3 is such that the center frequency of the pass band is selected to be equal to the center frequency of the color subcarrier f _Q , ie to be equal to 3.58 MHz in an NTSC system; in the pass band there is also a range of

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As a result, the luminance * signal Y ^ and the chrominance signal C _x , which are obtained from the adders 3 and 5, are each with respect to the amplitude in a range corresponding to the pass band of the delay circuit 2 compared to the amplitude in other ranges doubled, as shown in FIG. However, a low-frequency component of the chrominance signal C ^ of the adder 5 is not the chrominance signal but the luminance signal.

In this case, if the chrominance signal C ^ of the adder 5 is applied to a band-pass filter, its low-frequency component or that of the luminance signal can be removed so that only the chrominance signal C is output from the band-pass filter. However, if the frequency-amplitude curve of the luminance signal Y ,, of the adder 3 is made low, the following disturbance results. In order to make the frequency-amplitude curve of the luminance signal Y, - of the adder 3 low, it is sufficient to apply the luminance signal Yy to a bandstop filter with the characteristic shown in FIG. However, if the luminance signal Y _x . is treated in the aforementioned manner, a phase shift occurs in this luminance signal Y i, which causes overshoot or image doubling. In addition, it is rather difficult to provide a band elimination filter having the characteristic shown in FIG. 5 in accordance with the waveform of the luminance signal Y ^ shown in FIG. In the meantime, the original composite signal can be fed to a QIP filter in order to capture the low-frequency component of the luminance signal Y

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and filter out this low-frequency frequency component is with the luminance signal Y ^ of the adder 3 combined to form a · luminance signal with low frequency-amplitude curve. In such a case, however, the same may be the case Problem occur, such as when using a notch filter.

Referring to Figure 6, one is preferred Embodiment of the invention described which a comb filter for separating or filtering out the Luminance signals and the chrominance signal from the composite signal are used. The frequency-amplitude curve will low designed and a phase shift that is an overshoot and cause image doubling is avoided.

In Fig. 6, 11 denotes an input terminal to which a composite television signal is applied. This composite signal applied to the input 11 is fed to a bandpass filter 12, the center frequency of the pass band is selected to be equal to the frequency f of the color subcarrier and within whose pass band the pass band of the chrominance signal lies, as is shown in FIG. 7 by the solid line 13. This means that the passband of the bandpass filter 12 is selected such that it is 3.58+ in the NTSC system, for example. O _{5 is} 72 MHz. The output signal of the bandpass filter 12 is applied to a comb filter 14. This comb filter 14 consists of a delay circuit 15 that converts the signal applied to the filter

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one horizontal period delayed, as well as from a phase reversal circuit 16 and an adder 17 The signal obtained directly at the output of the bandpass filter 12 and that through the delay circuit 15 and the phase reversing stage 16 carried signals are combined in the adder 17. The. Delay circuit 15, which the signal by one horizontal period delayed, has a frequency response like the bandpass filter already described. As in Fig. 7 shown by the dashed line 18 is the pass band of the delay circuit 15 therein The case is somewhat larger than the pass band of the bandpass filter 12 corresponding to the solid line 13 chosen. An output to the connection 19 for the chrominance signal is led away from the adder 17.

The composite signal applied to the input 11 is also passed through a delay circuit 20 to an adder 21 for supplying a luminance signal. The band-pass filter 12 has the delay characteristic shown in FIG. 8 by the solid line 22. If the delay time of the bandpass filter 12 is set to Tj, the chrominance signal output at the output 19 is delayed by T i, as will be explained below. The delay circuit 20 can be a composite signal obtained, which is in phase with the abge given at the output 19 chrominance signal. The Verzögerungsechaltung 20 is consequently designed such that it has a band pass characteristic, so that a EBAS signal range of 0 to 4.2 MHz for an NTSC system is transmitted as shown in Fig. 7 by the line

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is shown; the delay circuit has in this pass band a constant time delay C ^, as indicated by the line 24- in Fig. 8 is shown. The delay or delay circuit 20 is designed in practice in such a way " that the delay time is adjustable.

The output signal of the adder 17 is applied to an amplifier 25 so that it is in terms of his Level selected or changed accordingly and in the Phase is reversed. The output of this amplifier 25 is applied to an adder 21 and then to the output of the delay circuit 20 combined. An output terminal 26 for the luminance signal is led away from the adder 21.

With the circuit explained above, a mixed signal consisting of a chrominance signal and a high-frequency component of the luminance signal is output at the bandpass filter 12. In the comb filter 14, the mixed signal, which is one horizontal period ahead of the mixed signal at this point in time, is subtracted from the former in order to eliminate the luminance signal component from this; the chrominance signal C without a luminance signal component is then output at the output 19. The amplitude curve of the chrominance signal C obtained in this way is shown in FIG. Since the time delay of the bandpass filter is 12 ^ C \ , the chrominance signal C output at output 19 is increased by u ^ compared to the chrominance signal contained in the FBAS input s signal

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- ίο -

hesitates. Since the composite input signal through the delay circuit 20 at 'T', delayed and then is applied to the adder 21, the fall in that from the delay circuit 20 to the adder 21 applied CVBS input signal The chrominance signal component and the component applied by the adder 17 via the amplifier 25 to the adder 21 The chrominance signal components coincide in time, but are reversed with regard to their phase. Puts one the gain of the bandpass filter 20 and the delay circuits 15 and 20 in view of the Chrominance signal components equal 1, so is the The amplitude of the chrominance signal component output by the adder 17 is twice as large as that in FIG chrominance signal component contained in that composite signal, which is applied to the adder 21 by the delay circuit 20. The amplitude of the Chrominance signal component e is therefore due to the amplifier 25 halved and the FBAS-ßignal sent by the delay circuit 20 to the adder 21 The chrominance signal component contained is equal to the chrominance signal component in terms of amplitude, which is given by the amplifier 25 to the adder. As a result, the chrominance signal component becomes eliminated in the adder 21 and a luminance signal Y. without a chrominance signal component obtain. Since the amplitude response or the transmission characteristics of the delay circuit 20 in is made flat in the manner described above, the luminance signal obtained at output 26 has a flat, i.e. low amplitude as shown in FIG is, and is not rotated with regard to its £ hare.

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Since the gain of the bandpass filter 12 and that of the delay circuits 15 and 20 do not are equal to 1, the levels of the two signals applied to the adder 17 and the level of the chrominance signal applied from adder 17 to adder 21 in the practical circuit in FIG Adjusted depending on the reinforcements.

According to the invention, the luminance signal and the Chrominance signal separated from the composite signal or can be removed from this without any mutual Interference occurs between these signals; In particular, a luminance signal is obtained that has a flat or low frequency amplitude. Has a gradient and has an excellent phase characteristic.

It is possible that the bandpass filter 12 to the rear Stage of the comb filter 14 to achieve the same effect is connected.

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Claims (5)

It 2988 claims 1. Circuit for supplying the luminance and chrominance signals from a composite television signal, characterized by a bandpass filter (12) with a pass band for a chrominance signal range of the composite signal, a comb filter (14), which is a delay circuit (15) with a one horizontal period corresponding delay time, the filter (15) connected in series with the bandpass filter (12) and a chrominance signal component extracts or delivers the composite video signal in connection with the bandpass filter (12) by a delay device (20) to delay the composite signal by a predetermined time interval so that this composite signal is in phase with the chrominance signal component, and by means (21, 25) for combining the Chrominance signal component with an output signal the delay device (20) with a predetermined polarity for removing or delivering a luminance signal component 2. A circuit according to claim 1, characterized in that the device (21, 25) for combining the chrominance signal component with an output signal of the delay device (20) has an amplifier (25) for 509810 / 072A Level control of the chrominance signal component and phase reversal of this component as well as a Adder (21) for adding an output signal of the amplifier (25) to the output signal the delay device (20). 5 09810/0724