KR0114433Y1 - Video signal converting circuit - Google Patents

Abstract

The present invention relates to a video signal conversion circuit, and more particularly, to a video signal conversion circuit capable of converting a digital luminance signal and a digital color difference signal into a digital color signal. In the video signal converter according to the present invention, the subtraction and multiplication processing is performed in the ROM, and the addition processing is performed in the Adder, thereby converting the digital luminance signal and the color difference signal into color signals in real time.

Description

Video signal conversion circuit

1 is a block diagram of a video signal conversion circuit according to the present invention.

* Explanation of symbols for main parts of the drawings

1, 3, 5, 6: 1st to 4th ROM 2, 4, 7, 9: 1st to 4th Adder

8: 2's complement converter

The present invention relates to a video signal conversion circuit, and more particularly, to a video signal conversion circuit capable of converting a digital luminance signal and a digital color difference signal into a digital color signal. Recommendation No. 6 established by the International Radiocommunication Advisory Committee (CCIR) stipulates a circuit for converting a digital luminance signal and a digital color difference signal, which are video signals, into a digital color signal. In general, digital color signals of R (red), G (green), and B (blue) can be generated by converting the digital luminance signal Y and the digital color difference signals Cb and Cr. Conventionally, when converting the digital luminance signal (Y) and the digital color difference signals (Cb, Cr) into digital color signals (R, G, B), the multiplication process is performed by a multiplexer or the like, and thus the digital color signals (R, G, B). There was a problem that cannot occur in real time. The present invention has been devised in view of the above-described problems, and is capable of converting a digital luminance signal (Y) and a digital color difference signal (Cb, Cr) into digital color signals (R, G, B) in real time. The purpose is to provide a circuit. A feature of the present invention for achieving the above object is, in the image signal conversion circuit for converting the digital luminance signal (Y) and the digital color difference signal (Cb, Cr), the digital color difference signal (Cr) is applied to a predetermined A first ROM for performing a subtraction and multiplication operation, a first adder 2 for adding a calculation data applied from the first ROM 1 and the luminance signal Y to output a digital color signal R, and the digital. The second ROM 3 which receives the color difference signal Cb and performs a predetermined subtraction and multiplication operation, the operation data applied from the second ROM 3 and the luminance signal Y are added to the digital color signal B. FIG. The second adder 4 for outputting the < RTI ID = 0.0 >), < / RTI > third ROM 5 for receiving a predetermined subtraction and multiplication by receiving the digital color difference signal Cb, and a predetermined subtraction after receiving the digital color difference signal Cr. And a fourth ROM 6 for multiplication, and a link applied from the third and fourth ROMs 5 and 6; A two's complement conversion key 8 for obtaining a two's complement for the operation data applied from the third adder 7 and the third adder 7, and the two's complement conversion key 8 for adding the acid data. And a fourth adder 9 for outputting the digital color signal G by adding the two's complement and the luminance signal Y. Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. The equation for converting the digital luminance signal Y and the digital color difference signals Cb and Cr into the digital color signals R, G and B is as follows. R = Y + 1.730 (Cr-128) (A) G = Y- {0.698 (Cr-128) +0.336 (Cb-128)} (B) B = Y + 1.370 (Cb-128) (C), where , Y, Cb, and Cr are 8-bit data, respectively, and the range of values is 16 to 235 for Y, and 16 to 240 for Cb and Cr.) The above formulas (A), (B) and (C) Thus, the digital luminance signal Y and the digital color difference signals Cb and Cr can be converted into the digital color signals R, G and B. 1 is a block diagram of a video signal conversion circuit according to the present invention. As can be seen from the figure, the video signal conversion circuit is composed of a plurality of ROMs, a plurality of adders, and a two's complement converter. Subtraction and multiplication are performed in the first, second, third and fourth ROMs (1, 3, 5, 6), and addition is performed in the first, second, third and fourth adders (2, 4, 7, and 9). The complement converter 8 finds a two's complement for subtraction. When the color signal R is generated from the luminance signal Y and the color difference signal Cr, the first ROM 1 uses the input color difference signal Cr in accordance with {1.370 (Cr-128)} of the formula (A). And the result is output to the first adder 2 side, and the first adder 2 adds the input luminance signal Y and the result from the first ROM 1 to add the color signal R. FIG. Output When the color signal B is generated from the luminance signal Y and the color difference signal Cb, the {1.730 (Cb-128)} expression (C) is used by using the color difference signal Cb inputted in the second ROM 3. The calculation is performed to output the result to the second adder 4 side, and the second adder 4 adds the input luminance signal Y and the result from the second ROM 3 to output the color signal B. FIG. .

When the color signal G is generated from the luminance signal Y and the color difference signals Cb and Cr, {0.366 × (Cb-128) of the formula (B) using the color difference signal Cb input to the third ROM 5. } And the result is output to the third adder 7 side, and the fourth ROM 6 uses the input color difference signal Cr to the {0.698 × (Cr-128)} of the formula (B). Is performed and the result is output to the third adder 7 side. The third adder 7 adds the calculation results from the third and fourth ROMs 5 and 6 and outputs the result to the two's complement converter 8 side. The two's complement converter 8 obtains the complement of the calculation result from the third adder 7 and outputs it to the fourth adder 9, and the fourth adder 9 is inputted with the input luminance signal Y and the second. The color signal G is output by adding the complement from the complement converter 8. As described above, the present invention converts the digital luminance signal and the color difference signal into a digital color signal by performing the subtraction and multiplication process in the ROM and the add process in the Adder, so that the color signal is not required to be multiplied by the multiplexer. It occurs in real time.

Claims (1)

In an image signal conversion circuit for converting a digital luminance signal (Y) and digital color difference signals (Cb, Cr) into digital color signals (R, G, B), the digital color difference signal (Cr) is applied to a predetermined subtraction and multiplication. A first ROM 2 for performing a calculation, a first adder 2 for adding a calculation data applied from the first ROM 1 and the luminance signal Y to output a digital color signal R; The second ROM 3 which receives the digital color difference signal Cb and performs a predetermined subtraction and multiplication operation, the operation data applied from the second ROM 3 and the luminance signal Y are added to the digital color signal ( The second adder 4 for outputting B), the third ROM 5 for receiving the digital color difference signal Cb and performing a predetermined subtraction and multiplication operation, and the digital color difference signal Cr. A fourth ROM (6) for subtracting and multiplying the data and arithmetic data applied from the third and fourth ROMs (5) and (6). 2nd complement 7 to obtain 2's complement for the operation data applied from the third adder 7 and 2's complement converter 8 obtained from the 2nd complement 7 And a fourth adder (9) for adding the complement and the luminance signal (Y) to output the digital color signal (G).