KR0140694B1 - High resolution image signal decoding circuit - Google Patents

Abstract

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Description

High resolution video signal demodulation circuit

1 is a video signal demodulation circuit diagram according to the present invention.

* Explanation of symbols for main parts of the drawings

10, 20, 30: first, second, third filter means 40: color demodulation means

21, 31, 45-48: 1st-6 filter 22, 32: 1st, 2nd mixer

41, 42, 44: First to third adders 43: Matrix part

The present invention relates to a method of demodulating up to a high frequency component of a video signal in a television receiver to improve the resolution of a screen.

In general, a television broadcasting system transmits a color signal and a luminance signal by multiplexing them in a reference frequency band. For example, in the case of the NTSC (National Television System Committee) method, the RY (red-luminance) and BY (blue-luminance) obtained by subtracting a color signal and a luminance signal are modulated into a carrier signal of a reference frequency band having a phase difference of 90 °. After generating an I (Inphase) signal and a Q (Quadrature Phase) signal, the IQ signal is multiplexed to generate and transmit a composite video signal. At this time, the luminance signal and the color signal transmitted are classified into frequency form according to the precision of how much the screen can be displayed, and the frequency of the current luminance signal and the color signal is unobtrusive to viewers watching the screen. Unbelievably low frequency components.

As a result, there is a limit to satisfying the viewer's desire to view the screen to be displayed more precisely through the current television receiver. The same applies to the broadcast method.

Therefore, various methods are emerging to satisfy the viewer's desire to view the precise screen as described above, and one of the high frequency luminance signals and color signals together with the existing low frequency component luminance signals and color signals is applied to the reference frequency band. Television transmission with multiple transmissions is emerging.

Accordingly, an object of the present invention is to demodulate not only the luminance signal and color signal of the low frequency component currently transmitted but also the luminance signal and color signal of the high frequency component to be transmitted newly, thereby improving the resolution of the screen. In providing.

In order to achieve the above object, the present invention provides a first filter means for separating a carrier signal and a luminance signal for a low frequency component color signal from a composite video signal, and a carrier signal for a high frequency color signal separated from the composite video signal. A second filter means for synthesizing, a third filter means for separating the high-frequency luminance signal from the composite video signal, and the high- and low-frequency luminance signals and the high- and low-frequency color subcarrier signals are synthesized and demodulated. It characterized in that it comprises a color demodulation means for generating them.

Hereinafter will be described in detail with the accompanying drawings the present invention.

FIG. 1 is a circuit diagram of an embodiment according to the present invention, which is a circuit for demodulating a video signal of an NTSC broadcasting system.

The first filtering means 10 separates the low-band luminance signal and the color subcarrier signal for the low-band color signal from the composite video signal input through the input terminal IP.

The second filter means 20 is a first filter 21 for separating the color carrier signal for the color signal of the high frequency from the composite video signal flowing through the input terminal (IP) and the output of the first filter 21 And a first mixer 22 for mixing the color carrier signal for the high frequency color signal with the first local oscillation frequency flowing through the line 1.

The third filter means 30 is a second filter 31 for separating the luminance carrier signal for the high-frequency luminance signal from the composite video signal flowing through the input terminal (IP) and the output of the second filter 31 And a second mixer 32 for mixing the luminance carrier signal with the second local oscillation frequency.

The color assisting means 40 is drawn from the color subcarrier signal for the low frequency color signal drawn from the first filtering means 10 and from the first mixer 22 included in the first filtering means 20. A second adder 41 for synthesizing a color subcarrier signal with respect to a high frequency color signal, a low-frequency luminance signal introduced from the first filter means 10, and the second filter included in the third filter means 30; A second adder 42 for synthesizing the high-frequency luminance signal input from the mixer 32, and a matrix unit 43 for demodulating the synthesized color part carrier signals output from the first adder 41 to generate color difference signals. ) And the synthesized color difference signals output from the matrix unit 43, respectively, with the synthesized luminance signal output from the second adder 41 to extract color signals, and then output them through the output ports OP1 to OP3. Between the third adder 44, the first filter means 10 and the first adder 41 The third filter 45 connected, the fourth filter 46 connected between the first filter means 10 and the second filter means 42, the first mixer 22 and the first filter. And a fifth filter 47 connected between the adders 41 and a sixth filter 48 connected between the second mixer 32 and the second adder 42.

Next, the operation of the circuit shown in FIG. 1 will be described.

The first filtering means 10 separates the color subcarrier signal for the low frequency color signal and the low frequency luminance signal from the composite video signal received through the input terminal IP and transmits the first and second output terminals, respectively.

The second filter means 20 separates the color subcarrier signal for the high frequency color signal from the composite video signal flowing through the input terminal IP. The second filter means 20 describes the constituent blocks. Color carrier carrier signal component for the first sub-mixer 22, and the first mixer 22 supplies the color carrier carrier signal component for the high frequency color signal output from the first filter 21 and the first local oscillation frequency supplied through the line (1). The subcarrier included in the color subcarrier signal component for the high frequency color signal is removed to extract the color subcarrier signal for the high frequency color signal.

The third filter means 30 separates the high-frequency luminance signal from the composite video signal flowing through the input terminal IP, and when the operation is explained for each component block, the second filter 31 uses the input terminal IP. The high-frequency luminance signal component is separated from the incoming composite video signal, and the second mixer 32 mixes the high-frequency luminance signal component with the second local oscillation frequency introduced through the line 2 to generate the high-frequency luminance signal. A subcarrier included in the time signal component is removed to extract a high-frequency luminance signal.

The color demodulation means 40 synthesizes the color carrier signals for the low and high frequency color signals, and then demodulates the synthesized color carrier signals into the color difference signals RY, BY, and GY. A luminance signal is synthesized, and the color difference signals RY, BY and GY are added to the synthesized luminance signal to extract color signals. Referring to the operation of the color demodulation means 40 for each component block, the first adder 41 is a color subcarrier for the low-frequency color signal introduced from the first filter means 10 through the third filter 45. The signal is added to the first mixer 32, and added to the color subcarrier signal for the high frequency color signal introduced through the fifth filter 47 to synthesize a frequency band of the color signal. The low-frequency luminance signal flowing from the first filtering means 10 through the fourth filter 46 is added to the low-frequency luminance signal flowing from the second mixer 32 through the sixth filter 48 to add luminance. The frequency band of the new scene is synthesized, and the matrix unit 43 removes the color carrier signals synthesized by the first adder 41 from the color carrier signals by reference color carrier signals having a constant phase difference. RY, BY, GY) and the third adder 44 The color signals R, G, and B are extracted by applying the color difference signals RY, BY, and GY demodulated by the matrix 43 to the luminance signal synthesized by the second adder 42, respectively. Send through the output ports OP1 to OP3. The third to sixth filters 45 to 48 are inserted to remove aliasing of the color subcarrier signal for the low and high frequency color signals and the high and low luminance signals, respectively. As a result, the color signals R, G, and B demodulated by the color demodulation means 40 have high resolution capable of displaying each part more delicately than the current television screen because the luminance and color signal components of the high range are alive. .

As described above, the present invention has the advantage that the resolution of the screen can be improved by demodulating the luminance signal and the color signal of a frequency band higher than the frequency band of the luminance and color signal currently received together with the luminance signal and the color signal currently being received. For example, if the current screen with a frequency band of 1.5 MHz in the color signal is 100 resolution, and the color signal in the band 0.3 MHz higher than the bandwidth of 1.5 MHz is additionally used, the screen resolution is about 60. There is an advantage to improve.

Claims (6)

A television receiver comprising: first filtering means for separating a carrier signal and a luminance signal for a low frequency component color signal from a composite video signal, and second filtering means for separating a carrier signal for a high frequency color signal from the composite video signal And a third filter means for separating a high frequency luminance signal from the composite video signal, and a color demodulation means for synthesizing and demodulating the high frequency and low frequency luminance signals and the high frequency and low frequency color carrier signals. High resolution video signal demodulation circuit comprising a. The first filter (21) of claim 1, wherein the second filter means (20) separates a color carrier signal for a high frequency color signal from a composite video signal flowing through an input terminal (IP). A first mixer for frequency-converting the color subcarrier signal for the high frequency color signal output from (21) to the first local oscillation frequency to remove the subcarriers included in the color subcarrier signal for the high frequency color signal; And a high resolution video signal demodulation circuit. The second filter unit (30) of claim 1, wherein the third filter unit (30) separates the luminance carrier signal for the high-frequency luminance signal from the composite video signal flowing through the input terminal (1P). And a mixer 32 for frequency-converting the luminance carrier signal, which is the output of the filter 31, by a second local oscillation frequency to extract the luminance signal of the high range from the luminance signal of the high range from the luminance carrier signal. High resolution video signal demodulation circuit. 4. The high resolution video signal demodulation circuit according to claim 2 or 3, wherein frequency bands of the first local oscillation frequency and the second local oscillation frequency are set differently. 2. The color demodulation means (40) according to claim 1, wherein the color demodulation means (40) is used for the color carrier signal for the low frequency color signal introduced from the first filter means (10) and for the high frequency color signal introduced from the second filter means (20). A first adder 41 for synthesizing the color subcarrier signal, a second low-frequency luminance signal input from the first filtering means 10, and a second high-frequency luminance signal introduced from the third filtering means 30; An adder 42 and a matrix unit 42 which demodulates the synthesized color carrier signal, which is the output of the first adder 41, and demodulates the color difference signal to generate color difference signals, and an output of the matrix unit 43. And a third adder 44 for extracting the color signals by adding the color difference signals to the synthesized luminance signal, which is the output of the second adder 41, and then transmitting the output color signals through the output ports OP1 to OP3. Video signal demodulation circuit. 6. The method according to claim 5, wherein the color demodulation means is connected to a rear end of the first filter means (10) to remove the aliasing of the color carrier signal for the low pass signal output from the first filter means (10). A third filter 45 and a fourth filter 46 connected to a rear end of the first filter means 10 to remove alizing of the low-frequency luminance signal output from the first filter means 10; And a fifth filter 47 connected to a rear end of the second filter means 20 to remove the alizing of the color carrier signal for the high frequency color signal output from the second filter means 20, and the fifth filter. And a sixth filter 48 connected to a rear end of the three filter means 30 to remove alizing of the high-frequency luminance signal output from the third filter means 30. .

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