KR980013451A - Gamma Correction Circuit for Color Correction - Google Patents

Abstract

A gamma correction circuit for color correction is disclosed. The gamma correction circuit includes a control unit that generates a gamma table selection control signal based on the input automatic brightness level signal, and a predetermined number of gamma in which a gamma coefficient corresponding to a predetermined number of gamma characteristics is stored for each channel corresponding to a plurality of color signals. A gamma table of each channel is enabled according to the gamma table selection control signal, and the gamma value of the luminance component of the color signal input to the address is corrected by the gamma coefficient stored in the enabled gamma table. Gamma corrected multiple color signals are read out.

Description

Gamma Correction Circuit for Color Correction

The present invention relates to a gamma correction circuit for color correction, and more particularly, to a gamma correction circuit for correcting luminance components included in a color signal input by a gamma coefficient corresponding to various gamma characteristics using a plurality of gamma tables. will be. In general, a luminance signal is attenuated in accordance with current and transmitted by an image signal picked up by an image pickup tube of a television broadcasting station. The video signal whose luminance component is attenuated is input to a device for reconstructing the original video signal, for example, a television receiver, and its gamma value is corrected. Here, a fundamental problem with television receivers is that there is a nonlinear relationship called gamma between the current and the luminance component between the output (picture tube) and the input (imaging). The main cause of this nonlinear relationship is the picture tube in the television receiver. Due to the operating characteristics of the electron gun constituting the picture tube, the beam current and the resulting luminance component do not change uniformly with the driving voltage, and the luminance component varies with almost square of the video driving voltage. This results in suppressing the lumps and stretching the whites. Therefore, a gamma correction circuit is required in a color display device such as a television receiver equipped with a color correction device because such a gamma error causes a serious error in color. The gamma correction circuit of a conventional television receiver has a problem in that a desired luminance level cannot be obtained because a gamma value based on one gamma characteristic curve is applied using a single gamma table having a predetermined gamma characteristic.

In order to solve the above problems, it is an object of the present invention to provide a gamma correction circuit for independently correcting each luminance component of a plurality of color signals before processing a plurality of input color signals. Another object of the present invention is to provide a gamma correction circuit for correcting luminance components of a plurality of input color signals by gamma coefficients corresponding to various gamma characteristics stored in a plurality of gamma tables. In order to achieve the above objects, a gamma correction circuit for color correction according to the present invention is adapted to an automatic brightness level signal input in a color correction device for outputting a plurality of color signals inputted by a predetermined conversion coefficient. A control means for generating a gamma table selection control signal and memory means including a predetermined number of gamma tables in which a gamma coefficient corresponding to a predetermined number of gamma characteristics is stored for each channel corresponding to a plurality of color signals; The gamma table of each channel is enabled according to the gamma table selection control signal, and the enabled gamma table reads a plurality of gamma-corrected color signals by correcting the gamma value of the luminance component of the color signal input to the address. It is characterized by shipping.

1 is a block diagram according to an embodiment of a gamma correction circuit for color correction according to the present invention.

FIG. 2 is a diagram illustrating a gamma characteristic curve based on gamma coefficients stored in the gamma tables illustrated in FIG. 1.

3 is a block diagram according to another embodiment of a gamma correction circuit for color correction according to the present invention.

Hereinafter, exemplary embodiments of a gamma correction circuit for color correction according to the present invention will be described with reference to the accompanying drawings. 1 is a block diagram according to an embodiment of a gamma correction circuit for color correction according to the present invention. A control unit 10 for inputting horizontal and vertical synchronization signals Hsync and Vsync from an automatic brightness circuit (not shown) and an automatic brightness level signal (hereinafter abbreviated as ABL) and a synchronization signal detector (not shown). The control signal output terminal of C1) is coupled to the enable terminal of each gamma table of the storage unit 20. For each of the plurality of color signals, a color signal is input to the address end of each gamma table of the storage unit 20 composed of a plurality of gamma tables, and the data output end thereof is coupled to the input end of the color correction device 30. A plurality of corrected color signals are output from the plurality of output terminals of the color correction device 30. Next, the operation of the circuit shown in FIG. 1 will be described with reference to FIG. 2. In Fig. 1, the controller 10 recognizes the level of the luminance signal according to the ABL signal and outputs a gamma table selection control signal for selecting a gamma table having a desired gamma characteristic. In addition, a period during which the gamma table selection control signal is generated in the controller 100 by inputting the horizontal and vertical synchronization signals Hsync and Vsync may be a vertical retrace period. The plurality of color signals are input as address signals of the gamma tables of the storage unit 20. Here, the plurality of color signals input to the storage unit 20 may be, for example, (R, G, B) or (Y, RY, BY) or (Y, U, V) or (Y, I, Q) signals. The following R, G and B signals are taken as examples. If the gamma characteristic curves for correcting the luminance component included in each of the input R, G, and B signals are n, the storage unit 20 generates gamma tables 21. 1-21. N for n Rs. and a gamma table (22. 1-22. n) for n Gs, and a gamma table (23. 1-23. n) for n Bs. For example, as shown in FIG. 2, if there are three gamma characteristic curves a, b, and c, there are three gamma tables of three channels for R. G and B of the storage unit 20. The gamma characteristic curve may be obtained by measuring a gamma matching the picture tube characteristic, or may be set to correct a gamma value only for a specific luminance level to give a desired effect to the screen. Each gamma table stores gamma coefficients according to gamma characteristic curves. In other words, the gamma characteristic curves illustrated in FIG. 2 will be described as an example. If the luminance signal inputted and the luminance signal outputted through the picture tube have an inverse gamma characteristic equal to a ', the first channel of each channel of the storage unit 20 will be described. The gamma table stores a gamma coefficient corresponding to a gamma characteristic (hereinafter, also referred to as a normal gamma characteristic), which is inversely related to the inverse gamma characteristic a '. The gamma (γ) value is expressed by the index of?, The gamma (a ') of the picture tube is 2.2, and the gamma of the normal gamma curve a required for correction is 0.4545 (= 1 / 2.2). In the second gamma table of each channel of the storage unit 20, a gamma coefficient according to a gamma characteristic such as b is stored to correspond to an input image signal that is too dark or too bright. That is, the gamma characteristic b has a higher output luminance level than the normal gamma characteristic a for a very low input luminance level, and a lower output luminance level than the normal gamma characteristic a for a very high input luminance level. In addition, the third gamma table of each channel of the storage unit 20 stores a gamma coefficient according to a gamma characteristic such as c having an output luminance level lower than a normal gamma characteristic with respect to the intermediate input luminance level. Accordingly, one gamma table of each channel is enabled according to the gamma table selection control signal generated by the control unit 10, and gamma correction is performed by stored gamma coefficients for color signals inputted to addresses from the enabled gamma table. The gamma corrected color signal is read out. In this case, the selected gamma table of each channel may have a different gamma characteristic or may have the same gamma characteristic. The color correction device 30 converts the read gamma corrected color signals Rr, Gr, and Br by a predetermined conversion coefficient and outputs the converted color signals Rc, Gc, and Bc. Here, the color correcting apparatus refers to a device for correcting the phase and magnitude of the color signal initially input to the color display device (TV receiver) and the phase and magnitude of the color signal finally output through the picture tube. This color correcting apparatus may be used by the same as the color correcting apparatus disclosed in Korean Patent Application No. 95-69696.

3 is a block diagram according to another embodiment of a gamma correction circuit for color correction according to the present invention. 3, the control signal output terminal of the control unit 100 for inputting the ABL signal from the auto brightness circuit (not shown) and the horizontal and vertical sync signals (Hsync, Vsync) from the sync signal detector (not shown) is used for storage. It is coupled to the address end of the memory 110. Each of the first to third gamma tables 121 to 123 receives R, G, and B signals, respectively, and each data input terminal is coupled to data output terminals of the storage memory 110, and each data output terminal. Is coupled to the input terminals of the color correction device 130. Color signals Rc, Gc, and Bc that have been color corrected are output from the output terminals of the color correction device 30. Next, the operation of the circuit shown in FIG. 3 will be described. In FIG. 3, the storage memory 110 stores gamma coefficients according to a plurality of gamma characteristic curves as shown in FIG. 2. The controller 100 outputs a selection control signal for selecting a gamma characteristic stored in the storage memory 110 according to the input ABL signal, and the storage memory 110 according to the gamma characteristic selected according to the selection control signal. The gamma coefficient is read out and output to the first to third gamma tables 121-123. The period during which the selection control signal is generated in the control unit 100 that inputs the horizontal and vertical synchronization signals Hsync and Vsync and the period in which the gamma coefficients are updated in the first to third gamma tables 121-123 are vertical retrace periods. . That is, the first gamma table 121 inputs the R signal as an address, and corrects the gamma value of the luminance component of the luminance component of the R signal inputted to the address in response to the gamma coefficient read from the storage memory 110. The second gamma table 122 outputs (Rr) and inputs a G signal as an address, and corrects the gamma value of the luminance component of the G signal inputted to the address in response to the gamma coefficient read out from the storage memory 110. And outputs a gamma corrected signal Gr, and the third gamma table 123 inputs the B signal as an address, and the luminance of the B signal inputted to the address in response to the gamma coefficient read out from the storage memory 110. The gamma corrected signal Br is output by correcting the gamma value of the component. Therefore, the luminance component of each of the input R, G, and B signals is corrected in response to the gamma coefficient read from the storage memory 110 in the first to third gamma tables 121-123, and the gamma corrected signal ( Rr, Gr, Br) are output to the color correction device 130. The color correction apparatus 130 converts the gamma corrected color signals Rr, Gr, Br read out from the first to third gamma tables 121-123 by a predetermined conversion coefficient, and converts the converted color signals Rc, Gc, Output Bc). Each gamma table illustrated in FIGS. 1 and 3 of the present invention may be implemented by a RAM, and the storage memory 110 illustrated in FIG. 3 may be configured by a ROM. Further, the gamma correction circuit shown in Figs. 1 and 3 may be configured at the rear end of the color correction device.

As described above, the gamma correction circuit of the present invention can measure the gamma corresponding to the picture tube (CRT) characteristics and apply an optimal gamma value due to a plurality of gamma characteristics, and corrects the gamma value only for a specific luminance level on the screen. You can give the specific effect you want.

Claims (9)

A color correction device for outputting a color signal converted from a plurality of input color signals by a predetermined conversion coefficient, the color correction device comprising: control means for generating a gamma table selection control signal based on an input automatic brightness level signal; and corresponding to a plurality of color signals Memory means including a predetermined number of gamma tables in which a gamma coefficient corresponding to a predetermined number of gamma characteristics is stored for each channel, and a gamma table of each channel is set according to the gamma table selection control signal. And a gamma correction circuit for outputting a plurality of gamma-corrected color signals by correcting a gamma value of a luminance component of a color signal input to an address by a gamma coefficient stored in an enabled gamma table. The gamma correction circuit for color correction according to claim 1, wherein the gamma correction circuit is configured at a front end of the color correction device. The gamma correction circuit for color correction according to claim 1, wherein the gamma correction circuit is configured at a rear end of the color correction device. The method of claim 1, wherein the plurality of color signals are any one of (R, G, B), (Y, RY, BY), (Y, I, Q) and (Y, U, V). Gamma correction circuit for correction. A color correction apparatus for outputting a plurality of input color signals by a predetermined conversion coefficient, the color correction apparatus comprising: storage means for storing gamma coefficients according to a predetermined number of gamma characteristics: the storage means based on an input automatic brightness signal Control means for generating a selection control signal for selecting the gamma coefficients stored in the memory; and updating the gamma coefficients read out from the storage means according to the selection control signal, and inputting a plurality of input color signals as an address to the plurality of color signals. And a plurality of gamma tables for correcting luminance components included in the gamma coefficients according to the gamma coefficients read from the storage means. The gamma correction circuit for color correction according to claim 5, wherein the gamma correction circuit is configured at a front end of the color correction device. The gamma correction circuit for color correction according to claim 5, wherein the gamma correction circuit is configured at a rear end of the color correction device. The color signal of claim 5, wherein the color signal is any one of (R, G, B), (Y, RY, BY), (Y, I, Q) and (Y, U, V). Gamma correction circuit for color correction. The gamma table of claim 5, wherein the plurality of gamma tables input an R signal as an address to correct a gamma value of the luminance component of the R signal according to the gamma coefficient read from the storage means, and output a gamma corrected R signal. First gamma table: A second gamma table and a B signal for inputting a G signal as an address, correcting a gamma value of the luminance component of the G signal according to the gamma coefficient read out from the storage means, and outputting a gamma corrected G signal. And a third gamma table for correcting the gamma value of the luminance component of the B signal according to the gamma coefficient read from the storage means, and outputting a gamma corrected B signal. Gamma correction circuit. ※ Note: The disclosure is based on the initial application.