KR100646295B1 - Circuit for Auto Color Enhancement - Google Patents

Abstract

The present invention relates to an automatic color enhancement circuit. The automatic color enhancement circuit of the present invention performs color extension on color data exceeding a threshold value among color data transmitted from a color converter and a color converter that converts input image data into color data except skin color data and outputs the color extension. Color data that does not exceed the threshold value includes a color enhancement controller that outputs as it is. According to the present invention, in order to guarantee a weak color purity in a display using a lamp light source to automatically saturate the R, G, B signal of a certain level or more to realize a more vivid color contrast, in general to the eyes of the user For ripe flesh, a natural and lively image can be realized by changing the signal level.

Display device, color purity, color contrast,

Description

 Automatic Color Enhancement Circuitry {Circuit for Auto Color Enhancement}             

1 is a view showing a color output conversion device according to the prior art.

FIG. 2 is a diagram illustrating a color output method by the color output converter according to the related art shown in FIG. 1.

3 illustrates an automatic color enhancement circuit in accordance with an embodiment of the present invention.

FIG. 4 is a diagram illustrating an operation of a color enhancement controller in the automatic color enhancement circuit shown in FIG. 3.
<Description of Symbols for Main Parts of Drawings>
100: video controller 110: color converter
200: luminance switch 210: skin color filter
220: skin color compensator 230: skin color converter
240: color converter 250: color enhancement controller
260: multiplexer

The present invention relates to a device for improving the image quality of a display device, and in particular, by saturating the weak color purity in a display using a lamp light source above a certain signal level, an automatic color to realize a more vivid color contrast It relates to an improvement device.

Recently, various video display devices have been introduced to accelerate the development of more clear and easy to use image display devices. In the development of such various video display devices, the interest of developers is focused on the realization of more vivid and natural colors. Typical flat panel displays include liquid crystal (LCD), plasma, DLP, LCoS, and the like.

The liquid crystal TV structure is largely divided into three types: color filter, liquid crystal, and backlight. The white light emitted from the backlight passes through the liquid crystal, and the amount of light is controlled. The white light is finally colored in a color filter that is color-coded by pixel units of red (R), green (G), and blue (B).

The liquid crystal is sandwiched between two polarizing plates which make the vibration direction of light constant. The voltage is applied to the liquid crystal to change the arrangement of the liquid crystal characters, thereby controlling the amount of light passing through to adjust the color intensity. With these technologies, the latest products represent about 1 billion colors. The voltage applied to the liquid crystal is a minute transistor (TFT) on a glass substrate.

The difference from the plasma is due to this structure. For example, the image quality is clear even in a place where the liquid crystal is brighter than the plasma. This is because the polarizer absorbs some external light such as lighting or sunlight, so the external light is not reflected on the screen. You can also make the screen brighter by making the backlight light stronger. The reason why liquid crystals are suitable for watching TV is that this characteristic is suitable because TV is often viewed in a bright room.

However, systems that control the light in the backlight with an array of liquid crystal molecules and a deflection filter create a "viewing angle" problem that can cause color blur when viewed from the side. Furthermore, the larger the screen, the higher the power consumption. As the number of cold cathode tubes used increases, so does the power consumption.

There is a drawback that liquid crystals are difficult to express completely black. This is because liquid crystals cannot completely block the light from the backlight even when displaying black images.

On the other hand, the light emission principle of plasma is the same as that of fluorescent lamps. Between two pieces of glass, “fine fluorescent lamps” coated with phosphors emitting red, green, and blue light are placed at high speeds. The reason plasma is suitable for large screens is that the manufacturing method is simple.

This feature is in contrast to liquid crystals. Liquid crystals require millions of transistors on glass substrates, requiring a high degree of precision. Therefore, although it is suitable for a small high-precision display, the larger the screen, the more difficult it is to spread the liquid crystal uniformly over the entire screen.

In terms of image quality, there is a characteristic that cannot be seen in liquid crystal. First of all, they have good expression on black. Unlike liquid crystals, where the backlight is always on, the plasma can be switched off by turning on the "fine fluorescent light" in the dark areas of the image. Therefore, light rarely leaks in the dark areas of the image like liquid crystals. Furthermore, there is no polarizing filter and no viewing angle problem peculiar to liquid crystals. Plasma is not only excellent in contrast because the black color is clear even in a dark room, but there is no change in image quality even when many people view it from any angle.

However, since there is no polarization filter, the external light is reflected on the screen, and thus the image is hard to see. The air layer between the glass with the front filter and the front glass substrate also causes reflection.

Plasma remains a problem in terms of luminous efficiency. Compared to fluorescent lamps, plasma is currently 1.5 to 1.8 lumens per watt (lm), while fluorescent lamps are 100 lumens per watt. This is why the screen of plasma is darker than liquid crystal.

The reason why the luminous efficiency is low is that the performance of the phosphor is insufficient. Increasing the voltage increases brightness, but it accelerates the aging of the phosphor and shortens its lifespan, which can also cause afterimages on the screen. The luminous efficiency problem is directly related to the image quality and the power consumption.

On the other hand, there is a rear projection TV that is in the spotlight as a third flat TV. Rear projection is simple in structure. The projector is installed inside the TV, and the image produced there is magnified with a lens to project from the inside of the screen. Depending on the part that produces the image used in the projector, the rear projection method is slightly different.

In the past, three types of CRTs, which are about 4 inches long, are used. CRTs are heavy and bulky, which makes them difficult to spread. Recently, small panels called micro-displays of 1-inch sizes, rather than CRTs, have emerged, making them slim enough to be called flat-panel TVs.

One of them is the type using 'transmissive liquid crystal'. In other words, light is transmitted from the back of the liquid crystal panel to the lamp to create an image.

The other is DLP (Digital Light Processing) of Texas Instruments. In the case of DLP, a micro display with a small number of pixels covered with fine mirrors called "Digital Micromirror Device" (DMD) is used. In other words, the light of the lamp is shot on the DMD to control the amount of light reflected by the mirror angle to produce an image.

Both of these methods use powerful lamps to overcome the dark screen, which is a drawback of the CRT method. Furthermore, by simply increasing the light intensity of the lamps, the image can be enlarged without expensive panels being made large.

Recently, a new micro display called LCOS (Liquid Crystal on Silicon) has emerged, enabling the creation of very delicate images that could not be realized by liquid crystal or plasma. The structure reflects the three LCOS panels with red, green, and blue light to produce three primary colors, and finally synthesizes them with a prism to produce a full color image.

One of the flat screen TVs using the new technology is SED. SED is one of the technologies called 'Field Emission Display' (FED), and the light emission principle is the same as CRT. Therefore, like the CRT, it is bright, has a clear contrast, and has a fast response time.

Applying the phosphor inside the screen is the same, but the method of colliding electrons with the phosphor is different. The CRT is a method in which an electron beam emitted from one electron gun is refracted by a powerful electromagnet called Deflection Yoke, which in turn strikes a phosphor. On the other hand, in the case of FED, the thickness is made thin by bonding a glass substrate coated with a phosphor and a glass substrate having an electron gun arranged as small as the number corresponding to the pixel. The FED is divided according to the shape of the electron outlet, and thus there are differences in characteristics.

It is organic EL that is expected to realize image quality that surpasses liquid crystal and plasma together with FED. Organic EL is called 'OLED (organic LED)' in Gumi, and it means LED made of organic material as its name. Flat-panel TVs using organic ELs can be described as arranging LEDs glowing in red, green and blue on a glass substrate.

LEDs generally use a compound semiconductor, which is an inorganic material, as a light emitter. The arrangement of several such LEDs is an LED display known as an electronic sign. However, in the case of flat-panel TVs, organic materials, such as diamines, which are not inorganic materials, are used as the light emitter. Inorganic materials are difficult to form crystals on the glass substrate, but organic materials are relatively easy in the manufacturing method. Organic EL is suitable for TVs because of its fast moving picture response speed and high resolution and contrast.

As described above, in the field of flat display, which has recently been rapidly increasing, the importance of clarity and natural color is increasing as a matter of determining the survival of the display.

1 is a view showing a color output conversion apparatus according to the prior art.

As shown in FIG. 1, a conventional Color Space Converter (CSC) 110, which is a simple color matrix, performs a Video Controller (VC) (Color Controller) to perform color output conversion. Colors of Y, U, and V signals input from 100) are changed to R, G, and B.

In this case, Y represents luminance, and U and V represent color difference signals of a blue system and a red system, respectively. When the Y, U, and V signals are input to the video controller (VC) 100, the video controller (VC) 100 adjusts the luminance (Y) to correct various image quality, and as a U, V signal, hue, saturation, etc. Will be adjusted.

In other words, when the user controls the video controller (VC) 100 to obtain the desired brightness or contrast, the video controller (VC) 100 converts the Y, U, and V signals generated according to the color converter ( CSC) 110. The color converter (CSC) 110 outputs R, G, and B according to the Y, U, and V signals.

FIG. 2 is a diagram illustrating a color output method by the color output converter according to the related art shown in FIG. 1.

As shown in FIG. 2, it can be seen that the color output according to the prior art is made linear. The color converter CSC linearly converts the input Y, U, and V signals into R, G, and B. That is, when the color adjustment value is given in the form as shown for the color output, the color is output in proportion to the adjustment value. Therefore, the color-converted output signal is finally converted into R, G, and B in the color converter (CSC) stage according to a given value in the system to represent an image.

However, in the display device without deterioration in color expression such as CRT, the conventional method was possible without any inconvenience, but in the Micro Display devices such as LCD, DLP, LCoS, etc. which use the latest lamp light source, Color purity issues are being raised.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and greatly improves the color contrast of a Micro Display device, which is limited due to the characteristics of a lamp light source, and even if the color is saturated at a certain level or higher, It is an object of the present invention to provide an automatic color enhancement circuit that can optimize image quality by keeping the skin color unchanged.

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Automatic color enhancement circuit of the present invention for achieving the above object is a color converter for converting the input image data to the color data, except the skin color data; And a color enhancement controller for performing color extension on color data exceeding a threshold value among the color data transmitted from the color converter, and outputting color data not exceeding the threshold value as it is.
The color converter may further include a skin color separation filter configured to separate image data input from the outside into skin color data and non-skin color data according to a preset skin color range.

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The skin color separation filter may further include a brightness switch that determines the contrast of the input skin color data.

In addition, the automatic color enhancement circuit of the present invention includes a skin color separation filter that separates video data input from the outside into skin color data and non-skin color data according to a preset skin color range; A skin color converter for converting skin color data separated from the skin color separation filter into color data; A color converter for converting non-skin color data separated from the skin color separation filter into color data; And a color enhancement controller for performing color extension on color data exceeding a threshold value among the color data transmitted from the color converter, and outputting color data not exceeding the threshold value as it is.

The skin color separation filter may further include a brightness switch that determines the contrast of the input skin color data.

The skin color converter further includes a skin color corrector for correcting skin color data separated by the skin color separation filter.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
3 is a diagram illustrating an automatic color enhancement circuit according to an embodiment of the present invention.

As shown in FIG. 3, the present invention can discriminate skin color from input component signals Y, U, and V, and a luminance switch 200 that detects a luminance component among the signals. Skin Color Band-Pass Filter (SCBF) 210, Skin Color Compensator (SCC) 220 to allow skin color correction to be more natural from discriminated skin color components. When finished, color correction is performed from the Skin Color Space Converter (SCSC) 230 and the Skin Color Filter (SCBF) 210, which converts to primary RGB for the original display. In order to convert the primary color signal to a primary color signal (Color Space Converter (CSC) 240), the primary color signal converted by the color converter (CSC) 240 according to a given threshold value A Color Enhancement Controller (CEC) 250 that allows color levels to be converted to the image, and a multiplexer 260 that mixes the final converted color and skin color and outputs them to the display signals R, G, and B. It is composed of

As illustrated, when component signals Y, U, and V, which are video data, are input from an external device or an IF terminal therein, the luminance switch 200 first performs brightness determination of the skin color signal for proper filtering of the skin color.

To this end, the brightness switch 200 classifies the brightness of the skin color signal into high and low according to a preset brightness value.

That is, the brightness switch 200 determines the contrast of the input brightness signal to distinguish between the skin color coefficient in the dark and the skin color coefficient in the bright. Accordingly, the luminance switch 200 may determine whether the skin color corresponds even when the brightness of the input signal is changed.

The skin color filter (SCBF) 210 discriminates the skin color from the color difference signals U and V, and performs appropriate skin color filtering according to image brightness according to the intensity information of the input signal transmitted from the luminance switch 200. That is, the skin color filter (SCBF) 210 selects a transmission target of the component signals Y, U, and V according to the skin color.

Therefore, the skin color filter (SCBF) 210 filters the signals coming into the skin color range among the component signals U and V components when the color difference signals U and V correspond to the skin color range, and thus the component signals Y, U, and V for proper correction. To the skin color compensator (SCC) 220.

Whether or not it corresponds to the skin color range can be set by the color coordinates, and the range can be changed according to the developer. Therefore, the skin color range has an arbitrary upper and lower limit set by the developer.

The skin color filter (SCBF) 210 sends the component signals Y, U, V to the color converter (CSC) 240 when the color difference signals U, V do not fall within the skin color range.

The skin color compensator (SCC) 220 performs appropriate correction to express the input skin color signal as a more natural skin color, and then transmits it to the skin color converter (SCSC) 230.

Skin color converter (SCSC) 230 converts the corrected skin color signal into a primary color signal for display.

The skin color filter (SCBF) 210 sends the component signals Y, U, V to the color converter (CSC) 240 when the color difference signals U, V do not fall within the skin color range.

The color converter (CSC) 240 converts the signal determined to be not skin color into R, G, and B primary color signals and then sends it to the color enhancement controller (CEC) 250 for color extension.

The color enhancement controller (CEC) 250 implements color enhancement on the R, G, and B primary color signals inputted from the color converter (CSC) 240 to enable sharper contrast. At this time, the output value for the input value becomes a non-linear relationship rather than a linear one-to-one correspondence.

That is, the color extension means converting the input video data value to the maximum value, and maximizing the desired color.

As described above, the skin color compensator (SCC) 220 performs correction for expressing the skin color as a natural skin color, but does not perform separate color extension. This is to prevent the natural color of the skin color from being damaged by the color extension.

The multiplexer (MUX) 260 combines the signal converted by the color enhancement controller (CEC) and the skin color signal transmitted from the skin color converter (SCSC) 230 and finally displays it to the user in the form of an output color signal RGB. .

FIG. 4 is a diagram illustrating an operation of a color enhancement controller in the automatic color enhancement circuit shown in FIG. 3.

As described above, the color enhancement controller (CEC) 250 performs color expansion on the R, G, and B primary color signals input from the color converter (CSC) 240, where the relationship between the input and the output is a nonlinear relationship. To achieve. Color extension takes the form of enlarging the data values for the R, G, and B primary color signals.

The color enhancement controller (CEC) according to the present invention sets a certain threshold value to determine whether to perform color extension.

In other words, the color enhancement controller CEC determines whether the threshold value is exceeded for each input primary color signal and converts the signal that exceeds the threshold value into the maximum signal that can be output.

When the input primary color signal falls below the threshold, the color enhancement controller CEC passes the input signal value as it is.

That is, as shown in FIG. 4, it can be seen that a linear relationship occurs before the threshold is exceeded, but a non-linear relationship occurs after the threshold is exceeded. This is because when the threshold is exceeded, the CEC converts the input primary color signal into the maximum signal that can be output.

The multiplexer MUX combines the signal converted by the color enhancement controller CEC and the skin color signals R, G, and B, and then displays the output color signals R, G, and B.

As described above, when the color is greatly extended in the display, a more natural and intense color contrast may be realized than the conventional display.

The technical spirit of the present invention has been described above with reference to the accompanying drawings, but this is by way of example only and not intended to limit the present invention. In addition, it is obvious that any person skilled in the art can make various modifications and imitations without departing from the scope of the technical idea of the present invention.

As described above, in order to guarantee weak color purity in a display using a lamp light source, the present invention saturates the R, G, and B signals more than a certain level to realize more vivid color contrast. As a result, a natural and lively image can be realized by not changing the signal level with respect to skin color familiar to the user.

Claims (12)

A color converter for converting input image data into color data except skin color data; And Automatic color, characterized in that it includes a color enhancement controller for performing color expansion on the color data exceeding the threshold value of the color data transmitted from the color converter, and outputs the color data that does not exceed the threshold value as it is. Enhancement circuit. The method of claim 1, The color converter further comprises a skin color separation filter for separating image data input from the outside into skin color data and non-skin color data according to a preset skin color range. The method of claim 2, The skin color separation filter further comprises a brightness switch for determining the contrast of the input skin color data. A skin color separation filter that separates video data input from the outside into skin color data and non-skin color data according to a preset skin color range; A skin color converter for converting skin color data separated from the skin color separation filter into color data; A color converter for converting non-skin color data separated from the skin color separation filter into color data; And Automatic color, characterized in that it includes a color enhancement controller for performing color expansion on the color data exceeding the threshold value of the color data transmitted from the color converter, and outputs the color data that does not exceed the threshold value as it is. Enhancement circuit. The method of claim 4, wherein The skin color separation filter further comprises a brightness switch for determining the contrast of the input skin color data. The method of claim 4, wherein The skin color converter further comprises a skin color corrector for correcting skin color data separated by the skin color separation filter. delete delete delete delete delete delete

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