KR100204224B1 - Automatic image control apparatus using blue/yellow signal sensor - Google Patents

Abstract

The present invention relates to a device for automatically correcting an image of an image display device that realizes an optimal image according to a surrounding environment. In the conventional image automatic correction device, a high price of R, G, B sensors is used, and thus the overall price of a product increases. In addition, the relative competitiveness of the product decreases, and the output value of the color signal processing units 8, 9, and 10 increases due to the heat generation during the operation of the amplifiers 81, 91, 101 applied to the respective color signal processing units 8, 9, and 10. As a result, accurate ambient brightness is not detected, there is a problem that the reliability of color correction of the image processed by the image processor 3 is reduced.

Accordingly, the present invention has been made to solve the above problems, by using the cyan-yellow sensor to detect the brightness of the environment as a cyan-yellow component, and from the detected cyan-yellow component of the red, green and blue It is an automatic image correction device using a cyan-yellow sensor that accurately detects color components and automatically corrects an image displayed on a screen, so that an image display device can faithfully reproduce natural colors to realize an optimal image.

Description

Automatic image correction device using cyan-yellow sensor

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image automatic correction device of an image display device that realizes an optimal image according to the surrounding environment. In particular, the brightness of the surrounding environment is converted into a cyan-yellow component using a cyan-yellow sensor. It automatically detects red, green, and blue color components from the detected cyan-yellow components, and automatically corrects the image displayed on the screen. The present invention relates to a device for automatically correcting an image using a cyan-yellow sensor to realize an optimal image.

1 is a diagram illustrating a conventional automatic image correcting apparatus using an RGB sensor for detecting red, green, and blue as means for detecting ambient brightness. The tuner tunes a predetermined channel among received signals received by an antenna ANT ( 1), a detector 2 for detecting an image signal of a channel selected by the tuner 1, and an image processor 3 for image processing such that the image signal detected by the detector 2 can be output on the screen. ), A CPT (Color Picture Tube) 4 which receives the image signal processed by the image processor 3 and outputs the image signal, and an audio signal reduced by the detector 2 may be output. A voice processing unit 5 for processing a voice so as to perform voice processing, a speaker 6 for receiving a voice signal processed by the voice processing unit 5 and outputting a voice signal, red (R), green (G), An RGB sensor 7 for detecting a blue component (B) and the RGB sensor 7 First to third color signal processing units (8), (9) and (10), and first to third color signal processing units (8) (9) which signal-process each detected color component (RGB) and output them as RGB color signals. A / D converter 11 converts the color signal RGB outputted from the < RTI ID = 0.0 > 10 < / RTI > into a digital signal and the digital color signal RGB output from the AD converter 11 to determine the current ambient lighting state. The microcomputer 12 controls the image processor 3 to achieve an optimal color reproduction according to the determined ambient lighting state.

In addition, the first color signal processing unit 8 includes a first amplifier 81 for amplifying a red (R) component input from the RGB sensor 7 at a predetermined amplification rate, and amplification of the first amplifier 81. Resistor (R1 to R4) for determining the rate, the resistor (R5) and the capacitor (C1) for filtering the red (R) component amplified by the first amplifier 81 to output a complete red (R) signal The second color signal processor 9 may include a second amplifier 91 for amplifying a green (G) component input from the RGB sensor 7 at a predetermined amplification rate, and amplification of the second amplifier 91. The resistors R7 to R10 that determine the ratio, and the resistors R11 and capacitor C2 that filter out the green (G) components amplified by the second amplifier 91 to output a complete green (G) signal. The third color signal processor 10 includes a third amplifier 101 for amplifying the blue component B input from the RGB sensor 7 at a predetermined amplification rate, and the third amplifier 101 of the third amplifier 101. Resistor (R13 to R16) for determining the amplification rate, and the resistor (R17) and condenser (C3) for filtering the blue (B) component amplified by the third amplifier 101 to output a complete blue (R) signal R6, R12, and R18, which are not described below, are resistors.

The operation of the conventional automatic image correcting apparatus configured as described above will be described with reference to FIGS. 1 to 3.

First, when a user supplies power to a television receiver and a received signal received by the antenna ANT is supplied to the tuner 1, the tuner 1 selects and outputs a channel of an input signal and detects it. The unit 2 detects the image tuned by the tuner 1, outputs an image signal to the image processor 3, and outputs an audio signal to the audio processor 5.

When the detected image and audio signals are input to the image processor 3 and the audio processor 5, the image processor 3 processes the input image signals and outputs the image signals to the CPT 4 so that a constant image is output. The screen is output, and the voice processing unit 4 processes the voice signal to be input and outputs the voice signal to the speaker 6 so that the voice of the screen output image is output.

On the other hand, when the image and audio are provided to the user as described above, the RGB sensor 7 of the ambient light sensor is a red (R), green (G), blue (B) component from the surrounding environment in which the television receiver is installed. Are detected and output to the first to third color signal processing units 8, 9 and 10, respectively, and the first to third color signal processing units 8, 9 and 10 are inputted from the RGB sensor 7. The red color component R, the green signal G, and the blue signal B are output to the A / D converter 11 by signal processing of the color component RGB.

3 is a waveform diagram illustrating red (R), green (G), and blue (B) components sensed and output by the R.G.B sensor 7.

Here, the operation of the first to third color signal processing units 8, 9 and 10 will be described in more detail as follows.

The first amplifier 81 of the first color signal processor 8 amplifies the red (R) component input from the RGB sensor 7 at a predetermined amplification rate set by the resistors R1 to R4 to convert the A / D. The resistor R5 and the capacitor C1 of the first color signal processor 8 filter the red R component amplified by the first amplifier 81 to remove noise by outputting to the unit 11. The red (R) signal is input to the A / D converter 11.

Since the second color signal processing unit 9 and the third color signal processing unit 10 are similar to the operation of the first color signal processing unit 8 described above, detailed descriptions thereof are omitted.

Meanwhile, when the color signals RGB are respectively output from the first to third color signal processing units 8, 9, and 10 as described above, the A / D converter 11 converts the input color signals RGB into digital signals. The microcomputer 12 converts the output to the microcomputer 12, and the microcomputer 12 is a digital color signal (RGB) input from the A / D converter 11 to determine the degree of brightness of the surrounding environment in which the current TV receiver is installed. By outputting a color correction value suitable for the brightness to the image processor 3, the color of the image processed by the image processor 3 is corrected for the current ambient brightness.

However, since the conventional image automatic correction device uses a high-priced RGB sensor, the overall price of the product rises, so that the relative competitiveness of the product decreases, and the amplifier 81 applied to each of the color signal processing units 8, 9, and 10. Since the output values of the color signal processing units 8, 9 and 10 are increased due to the heat generation during the operation of the cameras 91 and 101, accurate ambient brightness cannot be detected, and the reliability of the color correction of the image processed by the image processing unit 3 is high. There was a problem falling.

Accordingly, the present invention has been made to solve the above problems, by using a cyan-yellow sensor to detect the brightness of the surrounding environment as a cyan-yellow component, and from the detected cyan-yellow component of red, green and blue It is an object of the present invention to provide an automatic image correction device using a cyan-yellow sensor that accurately detects color components and automatically corrects an image displayed on a screen, thereby enabling an image display device to faithfully reproduce natural colors to realize an optimal image.

1 is a block diagram showing a conventional image automatic correction device.

2 is a circuit diagram showing the peripheral brightness detection means using the R.G.B sensor applied to the conventional automatic image correction device.

3 is a diagram showing the light detection characteristics of the R.G.B sensor applied to the conventional automatic image correction device.

Figure 4 is a block diagram showing an automatic image correction device using the teal-yellow sensor of the present invention.

Figure 5 is a circuit diagram showing the ambient brightness detection means using a teal-yellow sensor applied to the present invention.

Figure 6 is a diagram showing the light sensing characteristics of the teal-yellow sensor applied to the present invention.

7 is a chart comparing light sensing characteristics of an image automatic correction apparatus using a conventional R.G.B sensor and an image automatic correction apparatus using a cyan-yellow sensor of the present invention.

4 is a view illustrating an automatic image correcting apparatus using the cyan-yellow sensor of the present invention, and includes a cyan-yellow sensor 20 that detects and outputs a cyan component and a yellow component from input light. The blue detector 21 detects a blue component B value from the cyan component value output from the cyan-yellow sensor 20, and the yellow component value output from the cyan-yellow sensor 20. The green component (G) value is determined from the red detector 22 that detects the red component (R) value, and the blue (B) and red (R) output from the blue detector 21 and the red detector 22. The green detector 23 for detecting and the blue (B), red (R), and green (G) signals output from the respective detectors 21, 22, and 23 are converted into digital signals and the microcomputer 25 A / D converter 24 for outputting the current signal and the digital color signals R, G, and B output from the A / D converter 24 determine the current ambient lighting state. Side is composed of a microcomputer (25) for correcting an image by controlling the image processing unit 3 to be the best color reproduction according to the light conditions.

The blue detector 21 removes an output deviation of the first amplifier 211 and the first amplifier 211 that amplify the cyan component value detected by the cyan-yellow sensor 20 at a predetermined amplification rate. Resistors R20 to R22 for outputting the output value of the first amplifier 211 proportionally with respect to the cyan component value inputted therein, and resistors R23 and R24 for determining an amplification ratio of the first amplifier 211. And a red detector for filtering the signal amplified and output from the first amplifier 211 to output a complete blue signal B, and a blue signal B filtered from the condenser C20. The red detector 22 includes a second amplifier 221 which amplifies the cyan component value detected by the cyan-yellow sensor 20 at a predetermined amplification rate, and the resistor R26 feeds back to 22. Output value of the second amplifier 221 with respect to the yellow component value input by removing the output deviation of the second amplifier 221 Filters the resistors R27 to R29 to be output proportionally, the resistors R30 and R31 for determining the amplification ratio of the second amplifier 221, and the signals amplified and output from the second amplifier 221. Condenser C21 for outputting a complete red signal R, and a resistor R33 for feeding back the red signal R filtered by the condenser C21 to the blue detector 21, the green detector 23 denotes a third amplifier 231 for amplifying the blue signal B output from the blue detector 21 at a predetermined amplification rate, and a red signal R output from the red detector 22. And a resistor (R34 to R37) for outputting a green signal (G) by mixing the fourth amplifier (232) for amplifying at the amplification factor of the third amplifier (231) and the output signal of the third amplifier (231) and the fourth amplifier (232). The above-described reference numerals C22 and C23 are capacitors, and R25, R32, R38 and R39 are resistors.

Incidentally, the same components as in the prior art are denoted by the same reference numerals to avoid duplicate explanation.

The operation of the automatic image correcting apparatus of the present invention configured as described above will be described with reference to FIGS. 4 to 7.

First, when the television receiver is turned on by the user's power switching operation, the cyan-yellow sensor 20 receives the cyan component and the yellow component from the input light from the ambient light in which the television receiver is installed, that is, the indoor light in which the television receiver is installed. Detect the cyan component and output the cyan component to the first amplifier 211 of the blue detector 21, output the yellow component to the second amplifier 221 of the red detector 22, and output the blue detector 21 and the red detector. (22) detects blue (B) and red (R) from the input cyan and yellow components, and why the blue detector 21 and the red detector 22 input the cyan and yellow components, respectively. This is because the cyan and yellow components sensed and output by the cyan-yellow sensor 20 include blue (B) and red (R) components, respectively, as shown in FIG.

Here, the operation of the blue detector 21 and the red detector 22 will be described in more detail. First, the first amplifier 211 of the blue detector 21 may include a cyan component input from the cyan-yellow sensor 20. Amplified at a predetermined amplification rate determined by the resistors R23 and R24, and the capacitor C20 of the blue detector 21 performs a low pass filtering on the signal amplified by the first amplifier 211 to remove noise while completely removing the blue signal. (B) is output to the A / D conversion section 24.

In addition, the resistors R20 to R22 of the blue detector 21 remove the output deviation of the first amplifier 211 so that the output value of the first amplifier 211 is proportional to the input signal. The blue signal filtered and outputted by the reference) is fed back to the input terminal (-) of the second amplifier 221 constituting the red detector 22 using the resistor R26.

Meanwhile, the second amplifier 221 of the red detector 22 amplifies the yellow component input from the cyan-yellow sensor 20 at a predetermined amplification ratio determined by the resistors R30 and R31, and the red detector 22. Condenser C21 performs low pass filtering on the signal amplified by the second amplifier 221 to remove the noise so that the complete red signal R is output from the A / D converter 24.

In addition, the resistors R27 to R29 of the red detector 22 remove the output deviation of the second amplifier 221 so that the output of the second amplifier 221 is proportional to the input signal. The capacitor C21 The red signal R filtered and outputted from the N) is fed back to an input terminal (−) of the first amplifier 211 constituting the blue detector 21 using the resistor R33.

In the above description, the blue signal B detected by the blue detector 21 is fed back to the input terminal of the second amplifier 221 constituting the red detector 22, and the red signal R detected by the red detector 22. ) Is fed back to the input terminal of the first amplifier 211 constituting the blue detector 21 as follows.

In general, the lighting fixtures used in daily life vary slightly depending on the type, but most of them are made to be close to white light.

White light consists of a mixture of red, blue, and green, so different lighting fixtures have different color components.

In the case of fluorescent lamps, the blue component appears somewhat stronger than the red component, and incandescent lamps show the red component somewhat stronger than the blue component.

However, since the cyan-yellow sensor 20 detects and outputs a cyan component and a yellow component with respect to the input light, the cyan-yellow sensor 20 does not show a difference in output with respect to the characteristics of the ambient light and shows almost similar values.

Therefore, it is not suitable to use the cyan component and the yellow component as blue and red as it is.

Therefore, the blue signal B (the amplified value of the cyan component), which is the output signal of the blue detector 21, is fed back to the second amplifier 221 of the red detector 22, and the output signal of the red detector 22 is By feeding back the red signal R (amplified value of the yellow component) to the first amplifier 211 of the blue detector 21, the small difference in output of the cyan-yellow sensor 20 with respect to the ambient light is output to the first amplifier. At the outputs of the 211 and the second amplifier 221, it is made to be greatly highlighted so that it can be used as the blue signal (B) and the red signal (R).

That is, the values of the resistors R26 for feeding back the output signal of the first amplifier 211 and the values of the resistors R33 for feeding back the output signal of the second amplifier 221 are appropriately set. The amplification ratios of the amplifiers 211 and 221 are adjusted by appropriately setting the resistance values of the resistors R23 and R24 and R30 and R31 which adjust the input value and determine the amplification ratios of the amplifiers 211 and 221. By setting, the signals amplified by the respective amplifiers 211 and 221 can be taken as the blue signal B and the red signal R.

On the other hand, when the blue signal B and the red signal R are detected by the blue detector 21 and the red detector 22 as described above, the third amplifier 231 of the green detector 23 detects the detected signal. The amplified blue signal B is amplified and output at a predetermined amplification rate, and the fourth amplifier 232 amplifies and outputs the detected red signal R at a predetermined amplification rate.

The resistors R34 to R37 properly mix the output signal of the third amplifier 231 and the output signal of the fourth amplifier 232 to output the green signal G to the A / D converter 24.

That is, since the green component is commonly included in the cyan component and the yellow component, which are output values of the cyan-yellow sensor 20, as shown in FIG. 6, the green detector 23 and the blue detector 21 and the red detector ( The green signal (G) is detected by amplifying and mixing the blue signal (B) and the red signal (R) detected in 22, and taking the intermediate value thereof.

On the other hand, when blue (B), red (R), and green (G) are detected and input to the A / D converter 24 by the respective detection units 21 (22, 23) as described above, the A / The D converter 24 converts the input blue (B), red (R), and green (G) signals into digital signals and outputs them to the microcomputer 25. The microcomputer 25 receives the input digital color signals R, G, B) to determine the brightness of the surrounding environment, that is, the lighting state of the current TV receiver, and to provide the image processing unit 3 with a color correction signal that can reproduce the optimal image color with respect to the current lighting state. Therefore, the color of the image output on the screen to the CPT 4 is corrected and reproduced according to the current illumination state.

7 is a view illustrating light detection characteristics of a conventional automatic image correcting apparatus using an RGB sensor and an automatic image correcting apparatus according to the present invention using a cyan-yellow sensor, and the present invention using a cyan-yellow sensor as shown in FIG. It can be seen that the light sensing characteristics of the ambient brightness sensor of the inferior to the conventional ambient brightness sensor at all.

As described above, the present invention uses a cyan-yellow sensor to detect the brightness of the surrounding environment as a cyan-yellow component, and detects red, green, and blue color components from the detected cyan-yellow components. In addition, the image display device is an automatic image correction device using the cyan-yellow sensor to realize the optimal image by faithfully reproducing the natural color.

Claims (4)

The blue component (B) from the cyan-yellow sensor 20 that detects and outputs a cyan component and a yellow component from the input light, and the cyan component value output from the cyan-yellow sensor 20. A blue detector 21 for detecting a value, a red detector 22 for detecting a red component (R) value from a yellow component value output from the cyan-yellow sensor 20, and the blue detector 21. ) And a green detector 23 for detecting green component (G) values from blue (B) and red (R) output from the red detector 22 and the respective detectors 21, 22, and 23. ) Determines the current ambient lighting state using the blue (B), red (R), and green (G) signals output from the control panel, and controls the image processor 3 to achieve optimal color reproduction according to the determined ambient lighting state. Automatic image correction using the cyan-yellow sensor of the image display device, characterized in that consisting of a microcomputer 25 for correcting the image Value. The first and second amplifiers 211 and 2 of claim 1, wherein the blue detector 21 amplifies the cyan component value detected by the cyan-yellow sensor 20 at a predetermined amplification rate. Resistor (R20 to R22) to output the output value of the first amplifier 211 in proportion to the yellow component value input by removing the output deviation, and a resistor for determining the amplification rate of the first amplifier (211) R23 and R24, a capacitor C20 for filtering a signal amplified by the first amplifier 211 and outputting a complete blue signal B, and a blue signal B filtered by the capacitor C20. ) Is a resistor (R26) for feeding back to the red detector 22, automatic image correction device using a cyan-yellow sensor of the image display device. 2. The second detector 221 of claim 1, wherein the red detector 22 amplifies the cyan component value detected by the cyan-yellow sensor 20 at a predetermined amplification rate, and the second amplifier 221. Resistors R27 to R29 for outputting the output value of the second amplifier 221 in proportion to the yellow component value inputted by removing the output deviation, and a resistor for determining the amplification ratio of the second amplifier 221 ( R30 and R31, a capacitor C21 for filtering the signal amplified by the second amplifier 221 and outputting the complete red signal R, and a red signal R filtered from the capacitor C21. ) Is a resistor (R33) for feeding back to the blue detection unit 21, the automatic image correction apparatus using the cyan-yellow sensor of the image display device. The display device of claim 1, wherein the green detector 23 comprises a third amplifier 231 for amplifying the blue signal B output from the blue detector 21 at a predetermined amplification rate, and the red detector 22. The green signal G is output by mixing the fourth amplifier 232 for amplifying the output red signal R at a predetermined amplification rate, and the output signals of the third amplifier 231 and the fourth amplifier 232. Automatic image correction device using a cyan-yellow sensor of the video display device, characterized in that consisting of resistors (R34 ~ R37).