KR850003314Y1 - Width band chrominance demodulator - Google Patents

Abstract

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Description

Broadband color demodulation device

1 is a block diagram showing a conventional broadband color demodulation device.

2 is a block diagram illustrating a wideband color demodulation device for an embodiment of the present invention.

3 is a waveform diagram for explaining the operation of FIG.

4 (I) to (III) are circuit diagrams showing a specific example of the I signal processing apparatus of the present invention.

* Explanation of symbols for main parts of the drawings

1: comb filter 8: matrix circuit

9: band filter 10: I-axis demodulation circuit

11: Q-axis demodulation circuit 12, 14, 24: Low pass filter

20: color signal band variable stage 21: I signal processing circuit

23 variable gain control amplifier circuit 25 subtraction circuit

26: addition circuit

The present invention relates to a wideband color demodulation device such as a color television receiver, and more particularly, to a wideband color demodulation device capable of reducing color noise in a weak electric field when wideband color demodulation of a complex color television signal.

In general, the frequency color interleaving method of the carrier color and luminance signals in order to transfer the composite color television signal by NTSC method or the like to the maximum effective government within the allocated band and to be compatible with the black and white TV receiver. multiplexing (interleaving). This subcarrier frequency for color difference signal transmission is selected at an odd multiple of the horizontal frequency of the luminance signal and is determined to be 3.579545 [MHz] as is well known.

This subcarrier is a carrier suppression amplitude modulation of each of the two color difference signals to form a carrier color signal, which is added to the luminance signal and transmitted as a frequency interleaved signal. In addition, the color difference signal has a band of 0 to 1.5 [MHz] with an orange to cyan color having a high color discrimination power as an I signal in consideration of the fact that human visual characteristics differ from color to color. A low green to magenta color is used as the Q signal to have a band of 0 to 05 [MHz], and the subcarriers are modulated by the two color difference signals as described above. However, since the frequency of the subcarrier is 3.579545 [MHz] as described above, color noise is significantly increased during the weak electric field.

In particular, in the case of the wideband color demodulation device using the I and Q demodulation schemes shown in FIG. 1, since the signal-to-noise ratio (S / N) of the high frequency component of the I signal deteriorates, the color noise increases. This will be described with reference to the block diagram shown in FIG.

In the block diagram shown in FIG. 1, the comb filter 1 includes a horizontal horizontal syringe-to-relay circuit (hereinafter referred to as H delay circuit) 2, an addition circuit 3 and a subtraction circuit 4, and a feed stage. The delay from the delay delay circuit 2 while allowing the composite color television signal (hereinafter referred to as a composite video signal or video signal) applied to (5) to be supplied to the circuits 2, 3, and 4, respectively. An output signal is supplied to the addition and subtraction circuits 3 and 4. As a result, the luminance signal Y is extracted from the addition circuit 3 and the carrier color signal (chroma signal) from the subtraction circuit 4, respectively. The adder 3 of the comb-shaped filter 1 is connected to the matrix circuit 8 via a low pass filter 6 and an image amplifying circuit 7 whose output stages have a band frequency of 0 to 3.58 [MHz] and the luminance is high. The signal Y is input to the matrix 8.

The subtractor of the comb-flat filter 1 is connected to each of the input terminals of the I-axis and Q-axis demodulation circuits 10 and 11 via a chroma signal band pass filter 9 whose output end has a predetermined bandwidth. Each chroma signal is supplied. It is connected to each input terminal of the I-axis and Q-axis demodulation circuits 10 and 11 so as to supply chroma signals, respectively. The I-axis demodulation path 10 is connected to the matrix circuit 8 via a series circuit composed of a low pass filter 12 and a delay line 13 having an output terminal having a band of 0 to 1.5 [MHz]. And the I-axis assisted I signal are supplied to the matrix circuit 8. Similarly, the Q-axis demodulation circuit 11 is connected to the matrix circuit 8 via the low pass filter 14 whose output stage has a band characteristic of 0 to 05 [MHz], and performs Q- Q demodulated Q signal. It is configured to feed into the matrix ash 8. The matrix circuit 8 is configured to output three color difference signals R-Y, G-Y, and B-Y signals.

The operation of the wideband color demodulation circuit having the above configuration will be briefly described.

The composite video signal has a band of 0 to 4.2 [MHz] to carry the luminance signal, and carries out carrier suppression modulation of the video carrier and separates two color difference signals (I signal, Q) that are 3.579545 [MHz] away from the carrier. Signals have been carrier suppressed and modulated with each other, so that they are frequency interleaved and transmitted. The luminance signal of the composite video signal is obtained at the output end of the addition circuit 3 of the comb filter 1, is amplified after removing the required frequency through the low pass filter 6 and the image amplification circuit 7, and the matrix circuit 8 Is supplied.

On the other hand, the chroma signal in the composite video signal is obtained at the output end of the subtraction circuit 4 of the comb-type filter 1, and this is unnecessary through the band filter 90 having a band characteristic of about 2.1 to 4.1 [MHz]. The chroma signal, which is removed and supplied to the I and Q axis demodulation circuits 10, respectively, has a low pass filter 12 having a band characteristic of 0 to 1.5 [MHz] and a delay line for compensating the phase. It is supplied to the matrix circuit 8 via (13). In addition, the chroma signal supplied to the Q-axis demodulation circuit 11 is demodulated therein, and unnecessary components are removed through the low pass filter 14 having a band of 0 to 0.5 [MHz], thereby allowing the matrix circuit 8 to be removed. To feed.

The matrix circuit 8 forms and outputs the signals of (R-Y), (G-Y), and (B-Y) in accordance with the signals (Y, I, Q).

As mentioned above, since the I signal has a band of 0 to 0 to 05 [MHz], the resolution is significantly increased in accordance with the band of the transmitted I signal. However, the expansion of the band can achieve the purpose of increasing the resolution, which is a desired purpose in the time of war, but on the contrary, there is a drawback that the color noise is greatly increased during the electric field. Of course, if the band of the color signal is narrowed, for example, 0 to 1.5 [MHz], the color noise can be reduced, but there is a problem that color blur occurs and the quality of the reproduced image is deteriorated.

The present invention has been studied in view of the above points, and in other than the weak electric field, the color signal band is obtained in a wide band while the weak electric field is obtained. It is an object of the present invention to provide a wideband color demodulation device which has been raised and has greatly reduced color noise.

An embodiment of the present invention will be described below with reference to the drawings of FIG. 2.

2 is a block diagram of a broadband color demodulation device according to an embodiment of the present invention. In this figure, the same reference numerals are attached to the same elements as those in FIG. In this embodiment, the signal from the I-axis demodulator 10, the signal from the delay line 13, and the automatic gain control (AGC) signal are taken into the color signal band variable stage 20, and the signals are other than the weak electric field according to these signals. The color signal is obtained in a wide band and at the same time in a weak electric field, a color signal is obtained in a narrow band so that a color signal is supplied to the matrix circuit 8 in each case.

Here, the means for obtaining the AGC signal will first be described.

The means for obtaining the AGC signal is obtained by the intermediate frequency amplifier circuit 15 of the television receiver tuner (not shown), which is amplified by the image intermediate frequency amplifier circuit 15, and then detected by the image detector circuit 16 to become a composite video signal. 5) and at the same time connected to the AGC detection circuit 17, the AGC detection circuit 17 via the low pass filter 18, the amplification degree control stage 19 of the image intermediate frequency amplification circuit 15. And the color signal band are connected to the AGC signal input terminal P ₁₁ of the variable stage 20 so as to supply AGC signals, respectively.

The color signal band variable stage 20 to which the AGC signal is supplied to the input terminal P ₁₁ is configured as follows. That is, the I signal processing circuit 21 is connected to the control input terminal of the output variable gain variable control amplifier 23 of the amplifying circuit 22 for amplifying the AGC signal inputted from the input terminal P ₁₁ , and the variable gain control amplification. The amplification degree of the circuit 22 is changed according to the AGC signal. Also, an output signal from the delay circuit 13 (which has a bandwidth of 0 to 1.5 [MHz]) and an output signal from the I-axis demodulation circuit 10 are taken in to limit the bandwidth of 0 to 0.5 [MHz]. The output signal of the low pass filter 24 is input to the subtraction circuit 25. The subtraction circuit 25 subtracts both signals to apply an output signal of a band of 0.5 to 15 [MHz] to the input terminal of the variable gain control circuit 23. The output terminal of the I signal processing circuit 21 (in other words, the output terminal of the variable gain control amplifier circuit 23 is connected to the input terminal of the adder circuit 26 to supply the band-limited output signal.) 26 is configured to supply an output signal from the low pass filter 24 to the other input terminal, and add this signal and the signal from the I signal processing circuit 21 to supply to the matrix circuit 21. .

The operation of the signal band variable stage configured as described above will be described with reference to FIG.

FIG. 3 is a waveform explanatory diagram for explaining the operation of FIG. 2, in which the drawing I shows the band characteristics of the low pass filters 12 and 24, and the drawing II shows the band of the subtraction circuit 25. FIG. The characteristic figure shows the band characteristic of the addition circuit 26, respectively, and the frequency f [MHz] is taken to the horizontal axis of each figure, and the response is taken to the vertical axis | shaft.

First, the input intermediate frequency signal is amplified by the image intermediate frequency amplifier circuit 15 and then converted into a composite image signal by the image detection circuit 16. At this time, in order to keep the output level of the composite video signal constant, the image intermediate frequency amplification circuit 15 uses a variable gain controllable amplification circuit. The composite video signal is detected by the AGC detection circuit 17. The gain of the image intermediate frequency amplification circuit 15 is controlled with the signal via the low pass filter 18, and the level of the composite image signal is not changed by the intensity of the received electric field. As a result, the output signal of the low pass filter 18 becomes a signal according to the electric field strength.

The composite video signal supplied to the feeder stage 5 is separated into the luminance signal r and the chroma signal by the comb filter 1 as described above. The chroma signal is demodulated into I and Q signals by demodulators 10 and 11 after passing through the band pass filter 90. This Q signal is supplied to the matrix circuit 8 which is band-limited by the low pass filter 14 having a predetermined band characteristic (0.4 to 0.5 [MHz]) and added at a predetermined addition ratio.

On the other hand, the I-signal has a low pass filter 24 having a predetermined band characteristic (for example, 0 to 1.5 [MHz]) and a predetermined band characteristic (third (I) as in the waveform (a) of FIG. 3 (i)). Waveform 3 (b) in the figure is also band-limited, for example, by a low pass filter 12 having a frequency of 0 to 1.5 [MHz], such as a waveform, and an output signal of the low pass filter 12 is delayed for group delay compensation. After the circuit 13, it is supplied to the subtraction circuit 25. Again, the output signal of the low pass filter 24 is supplied to the subtraction circuit 25 to output the band characteristic shown in FIG. That is, the output signal of the subtraction circuit 25 becomes only the high frequency component of the I signal (for example, 0.5 to 1.5 [MHz]), and the high frequency component of the I signal thus obtained is the variable gain control amplifier circuit 23. And then amplified by the addition circuit 26, it is added to the output signal of the low pass filter 24. The output of the addition circuit 26 is supplied to the matrix circuit 8 to supply a predetermined color difference signal (R -Y), (G-Y) and (B-Y) signals).

However, the variable gain control amplifier circuit 23 changes its amplification degree in accordance with the AGC signal amplified by the amplifier circuit 22. As a result, the level of the high frequency component (see also third (II)) of the I signal from the subtraction circuit 25 is controlled by the amplifier circuit 23 in accordance with the level of the signal. At the time of medium and strong detection, the amplification circuit 23 outputs the output signal (high frequency component of the I signal) by the amplifying circuit 23 so that the output of the adding circuit 26 becomes the signal shown in FIG. Increases the level by only 6 [dB]. On the contrary, during the weak electric field, the output signal of the subtraction circuit 25 is attenuated to zero level. That is, the output of the addition circuit 26 is a signal of only the band b which does not contain the signal of the band b in FIG. 3 (III).

As described above, depending on the strength of the received electric field, the band of the color signal becomes, for example, 0 to 1.5 [MHz] except for the weak electric field, and increases the level of the high frequency component, and for example, 0 to 0.5 [MHz] for the weak electric field. It is to be made. As we did in this way, resolution except weak electric field time. Sharpness is remarkably improved, and color noise can be significantly reduced at the time of weak electric field.

Next, specific examples of the I signal isolation circuit 21 will be described with reference to FIGS. 4 (I) to 4 (III).

4 (I) is a circuit diagram showing an embodiment of the I signal processing circuit 21. As shown in FIG. The AGC signal from the low pass filter 18 is supplied to the base of the transistor Tr1 via the resistor RO, amplified by the transistor Tr1 and then connected to the base of the transistor Tr2. The collector of the transistor Tr1 is connected to the power supply Vcc, and the emitter is configured to be supplied to the base of the transistor Tr2. That is, the collector of transistor Tr2 is connected to the cathode of diode D1, and its emitter is connected to the connection point of the series circuit of resistors R1 and R2 connected between the power supply Vcc and ground. The anode of the diode D ₁ is connected to the power supply Vcc. The transistor Tr2 collector is again connected to the emitter of the transistor Tr ₃ via the capacitor C ₁ and the resistor R ₃ . And a ground via the emitter resistance R ₃ of the transistor Tr3 that the collector is connected to the power source Vcc that the base is connected to the output terminal of the subtracting circuit 25. The base of the transistor Tr4 is connected to the connection point of the capacitor C ₁ and the resistor R ₃ , the collector is connected to the power supply Vcc, and the emitter is grounded via the resistor R ₅ . Then, the high frequency component of the I signal is taken out from the emitter.

According to this circuit, the transistor Tr ₂ conducts when a voltage higher than the threshold determined by the resistors R ₁ and R ₂ is applied to the base, and the high frequency component of the signal is blocked and output from the low pass filter composed of the resistor R ₃ and the capacitor C ₁ . Do not.

Therefore, as the AGC signal, the level is low when the electric field is strong and the level is high when the electric field is weak. At this time, the color signal is high in the midfield and the color signal (I signal) is narrow in the weak field. Will be transmitted in band.

4 (II) shows a wider band at a stronger electric field than a predetermined electric field as in the same diagram (I), and transmits an I signal of a color signal in a narrow band at a weak electric field. In this figure, the same reference numerals are given to the same elements as in the same drawing (I), and description thereof is omitted. This configuration is characterized in that the differential amplification circuit is constituted by the transistors Tr ₅ and Tr ₆ to form the subtraction circuit 25 and the collector resistor R ₃₀ of the transistor Tr ₆ is also combined with the resistor R ₃ . That is, the output signal of the delay circuit 13 is supplied to the base of the transistor Tr ₅ , and the output signal of the reduction filter 24 is supplied to the base of the transistor Tr ₆ , which is paired with this, and the collector of the transistor Tr ₆ is supplied. The subtracted output signal is taken out and supplied to the base of the transistor Tr ₄ . That is, the emitters of the transistors Tr ₅ and Tr ₆ are made common through the resistors Tr ₆ and Tr ₇ , and grounded through the constant current source Io, the collector of the transistor Tr ₅ is connected to the power supply Vcc, and the collector of the transistor Tr ₆ is connected. via a resistor R ₃₀ is respectively connected to the power supply Vcc.

According to this circuit, it is turned on by the AGC signal. The transistor Tr ₂ controlled to be off is alternatingly swung.

The fourth (III) is another embodiment of the signal processing circuit 21. The configuration of this figure is an example of a concrete circuit in the case where the gain of the variable gain control amplifier circuit 23 is changed linearly. The structure of this figure is as follows. Transistor Tr supplies the AGC signal from the low pass filter 18 on the base _7, and supplies a bias from the bias power source E to the base of the transistor Tr ₈ in the pair with it, and each emitter of the transistors Tr _7, Tr ₈ The resistors are made common through the resistors Tr ₈ and Tr ₉ and are connected to the collector of the transistor Tr ₉ . The signal from the subtraction circuit 25 is supplied to the base of the transistor Tr ₉ . Finally, the high frequency component of the I signal is taken out from the collector of the transistor T ₈ . The collector of the transistor Tr ₁ is connected to the ground of the power supply Vcc and the collector of the transistor Tr ₈ via the resistor R ₁₀ via the resistor R ₁₁ of the emitter of the transistor Tr ₉ via the power supply Vcc.

Thus, although the I signal processing circuit 21 is constructed, the yoke is designed to reduce the color noise by narrowband transmission of the color signal at the start of the pharmacopeia, and to increase the resolution and sharpness by transmitting the broadband at the beginning of medium and high power. All configurations are included in the present invention.

As described above, according to the present invention, the band is varied according to the received electric field strength, and when the weak field is obtained, the color signal is obtained in the narrow band and the color signal is obtained in the wide band. In addition, there is an effect that can significantly reduce the color noise.

Claims (1)

A wideband color demodulation device for demodulating a Q signal and a carrier signal modulated with an I signal having a wider bandwidth than the Q signal, comprising: a comb filter 1 for extracting a luminance signal and a carrier color signal from a composite video signal, respectively; Q-axis demodulation circuit 11 which takes in a carrier color signal from comb filter 1 and demodulates it to form a Q signal, and an I-axis demodulation circuit which takes in the carrier color signal and demodulates it to form an I signal. The furnace 10, the delay circuit 13 which takes in the I signal from the I-axis demodulation circuit 10 and delays it for a predetermined time, and the I signal from the I-axis demodulation circuit 10, and A delay output signal from the delay circuit 31 and an automatic gain control signal for preventing the level of the composite video signal from fluctuating are inputted accordingly. In the I signal A matrix circuit 8 which receives the color signal band variable stage 20, the luminance signal, the first color signal, and the I signal from the color signal band variable stage 20, adds a predetermined value, and obtains a color difference signal; Broadband color demodulation device comprising a.