KR20080054329A - Apparatus for compensating image, method for compensating image, a recording medium storing program to implement the method, and apparatus for displaying image - Google Patents

Abstract

An apparatus and a method for compensating images, a recording medium having a program for utilizing the method, and an apparatus for displaying images are provided to adjust a compensation value using an adjustment value by setting the compensation value for every line based on an image signal from outside. An apparatus for compensating images includes a line load calculating unit(102), a compensation value setting unit(104), a whole load calculating unit(106), a compensation value adjusting unit(108), and an image signal compensating unit(112). The line load calculating unit calculates loads for every scan line based on an image signal from outside. The compensation value setting unit sets a compensation value for compensating the image signal based on the calculation result for every line. The whole load calculating unit calculates whole load for full screen. The compensation value adjusting unit adjusts the compensation value for every line based on the calculated whole load. The image signal compensating unit compensates for the inputted image signal based on the adjusted compensation value.

Description

Apparatus for compensating image, method for compensating image, a recording medium storing program to implement the method, and apparatus for displaying image}

1 is a diagram for describing a problem occurring in a conventional video display device.

FIG. 2 is a diagram for explaining a problem arising in the conventional art of correcting an image signal using a correction value determined based on a load for each line.

FIG. 3 is a diagram for explaining correction of an image signal in an image correction apparatus according to the related art, which corrects an image signal using a correction value determined based on a load per line.

4 is a block diagram showing an image correction device according to an embodiment of the present invention.

5 is a diagram for explaining correction of a video signal in an image correction device according to an embodiment of the present invention.

6 is a flowchart illustrating an image correction method according to an embodiment of the present invention.

7 is a block diagram illustrating a video display device according to an embodiment of the present invention.

<Explanation of symbols for main parts of the drawings>

100: image correction device 102: line load calculation unit

104: correction value setting unit 106: total load calculation unit

108: correction value adjusting unit 110: video signal delay unit

112: video signal correction unit 114: load calculation unit

116: adjustment value setting unit 200: video display device

202: Image correction unit 204: Image display unit

206: display unit 208: row driving unit

210: heat drive unit 212: power supply unit

214: control unit

The present invention relates to an image correction apparatus, an image correction method, a recording medium on which a program for performing the same is recorded, and an image display apparatus.

Recently, as an image display device replacing a CRT display (Cathode Ray Tube display), it is also called an OLED display (Organic Light Emitting Diode display; or organic electroluminescence display), FED (Field Emission Display) Various image display devices such as LCD (Liquid Crystal Display) and PDP (Plasma Display Panel) have been developed.

In general, the video display device described above is driven in a matrix manner to display an image on a screen. That is, the above-described image display apparatus includes a display unit (screen) in which pixels are arranged in a matrix form, and a driving unit which applies scan signals or image signals in row and column directions, respectively, to emit light of the pixels and display an image. It is provided.

For example, a typical PDP includes two sustain electrodes to which scan signals are applied in the row direction (horizontal direction) of the display unit (screen), and data electrodes (address electrodes) to which image signals are applied in the column direction (vertical direction) of the screen. Has In addition, an area where the sustain electrode group and the data electrode group cross each other becomes a display area. The PDP discharges and emits light by applying a sustain pulse as a scan signal to the sustain electrode, and displays an image indicated by the video signal applied to the data electrode on the screen.

Here, it is preferable that the gray level of the image displayed on the screen changes at a constant rate according to the change of the image signal. For example, when the gradation is displayed in 8 bits, uniformity is performed in one step, from the minimum gradation 0 (in which "black" is displayed) to the maximum gradation 256 (in which "white" is displayed).) Ideally, the gradation changes in one proportion. However, in a PDP, for example, a voltage drop occurs due to the influence of the sustain electrodes and data electrodes of the display unit, the internal impedance of the driver unit, the wiring impedance, and the like, and the luminance of the video signal is not maintained but the luminance is maintained. As a result, the phenomenon that the gradation did not change at a constant rate occurred.

The above problem will be described with reference to FIG. 1, which is a diagram for explaining a conventional problem occurring in the video display device. For example, as shown in FIG. 1A, a display area (A, C) having a large area for displaying white and a display area (B) having a small area for displaying white are displayed. The load applied to each of the sustain electrodes constituting the display regions A and C is greater than the load applied to each of the holding electrodes constituting the display region B. FIG. At this time, the image displayed on the screen of the video display device is displayed in the display area B because the brightness of the white color displayed in the display areas A and C as shown in FIG. It is lower than the luminance of white displayed. Therefore, in the conventional video display device, even if the video signal applied to the portion displaying white in the display areas A to C is a signal corresponding to the same gray level 255, the luminance difference occurs as shown in Fig. 1B.

The above-mentioned problem is a case where the video signal shows the minimum gray level 0 ("black" is displayed at this time) and the maximum gray level 256 ("white" is displayed at this time) as shown in Fig. 1A. The present invention is not limited thereto and occurs when there is a load difference in each of the sustain electrodes formed in the horizontal direction of the screen (that is, the direction in which the scan signal is applied).

In addition, the above-described problem is not limited to the PDP, and for example, a self-luminous image display device such as an OLED display, an FED, or a video display device having a different light emission method such as a backlight image display device such as an LCD may occur. do.

In such a center, the video signal component is monitored for each line in the horizontal direction of the screen (i.e., the direction in which the scan signal is applied), and the continuity of the pixels displaying the video signal representing black and the pixels displaying the video signal representing white are displayed. A technique for calculating the load per line based on the continuity of and further correcting the video signal using the correction coefficient determined based on the load for each line has been developed. As a technique of correcting a video signal using the correction coefficient determined based on the load for each line, Japanese Patent Application Laid-Open No. 2005-62337 is mentioned.

However, the conventional technique of correcting a video signal by using a correction coefficient determined based on the load per line is based on the continuity of pixels displaying an image signal representing black and the continuity of pixels displaying an image signal representing white. Since it is a structure which calculates the load for every one line and determines a correction coefficient based on this, a new problem may arise because of such a structure.

FIG. 2 is a diagram for explaining a problem caused in the conventional art of correcting an image signal by using a correction coefficient determined based on a load for each line. Here, the display areas A and C in FIGS. 2A to 2C are the same display areas as the display areas A and C in FIG. 1 described above.

Referring to FIG. 2A, for example, when a video signal is not determined that the pixel is displaying a video signal indicating black as shown in the display area D of FIG. 2A. Even if the pixels are continuous, it is not determined that the pixels displaying the video signal representing black are continuous. Therefore, in Fig. 2A, the video signal is not corrected, but there is a difference in the degree of brightness as shown in Fig. 1B.

2 (b), for example, as shown in the display area (E) of FIG. 2 (b), a video signal in which a continuous amount of pixels displaying a video signal in black is displayed is black. If it is smaller than the threshold value used for the determination of the continuity of the pixels to be displayed, it is not determined if the pixels displaying the video signal showing black are continuous. Therefore, in Fig. 2 (b), the video signal is not corrected, but there is a difference in the degree of brightness as shown in Fig. 1 (b).

Moreover, the conventional technique of correcting a video signal using the correction coefficient determined based on the load per line has a problem that the correction of the video signal is not effective even if the load on one line is the same. Here, in the case where the load applied to one line is the same, for example, the number of pixels displaying black in one line is the same, but the pixels displaying black as shown in the display area E of FIG. And the case where the pixels displaying black are dispersed as shown in the display region F of FIG. 2C. Although the continuity of the pixel which displays the video signal which shows black was mentioned as the example above, the continuity of the pixel which displays the video signal which shows white is the same.

As described above, the conventional technique of correcting a video signal using the correction coefficient determined based on the load for each line includes a continuity of pixels displaying a video signal representing black and a video signal representing white. Since the correction factor is determined by calculating the load per line based on the continuity of the pixels, the video signal is corrected according to the video indicated by the video signal (for example, in the case of Fig. 1A). Or not (for example, in the case of Figs. 2A to 2C).

Here, the correction performed in the conventional technique of correcting the video signal using the correction coefficient determined based on the load for each line is shown, for example, as shown in FIG. Fig. 3 shows a load ratio of one line indicating a load calculated based on the continuity of pixels displaying video signals showing black on the horizontal axis and the continuity of pixels displaying video signals showing white, and the vertical axis of the video signals. It is a figure which shows gain.

Referring to FIG. 3, the conventional technique of correcting a video signal using a correction coefficient determined based on a load for each line is based on whether or not the load ratio of one line indicated on the horizontal axis exceeds a predetermined threshold a. It is determined whether or not the video signal is corrected. Therefore, for example, the video signal should be corrected as shown in Figs. 2 (a) to 2 (c), or when the video signal originally to be corrected due to various effects such as noise on the video signal is not corrected. In the case where it is not determined and in the case where it is determined that the video signal should be corrected, the conventional problem shown in Fig. 1 is not solved and a luminance difference occurs. In particular, when the load of one line indicated by the video signal continuously input to the image correction device is about or before the threshold value a, the luminance difference becomes clear depending on the presence or absence of correction.

As described above, the conventional technique of correcting a video signal using the correction coefficient determined based on the load for each line is a case where the correction of the video signal becomes effective according to the video signal for calculating the load for each line. There is a problem that the luminance difference of the displayed image may become clear due to the fact that it becomes invalid.

Therefore, the present invention has been made in view of the above problems, and an object of the present invention is a novel and improved image correction device and image correction method capable of correcting an image signal for each line in a scanning direction based on an input image signal. And a program and a video display device.

In order to achieve the above object, according to the first aspect of the present invention, a line load calculating section for calculating a load applied to each line in the scanning direction based on the input video signal and based on the calculation result of the line load calculating section A correction value setting unit for setting a correction value for correcting an image signal for each line, a total load calculation unit for calculating an overall load on the entire screen when the input image signal is displayed on a screen, and the total A correction value adjusting unit for adjusting each of the correction values for each line set by the correction value setting unit based on the total load calculated by the load calculating unit, and based on the correction value for each line adjusted by the correction value adjusting unit There is provided an image correcting apparatus including an image signal correcting unit configured to correct the input image signal.

The image correcting apparatus includes, for example, a line load calculating section, a correction value setting section, a total load calculating section, a correction value adjusting section, and a video signal correcting section. The line load calculator can calculate the load applied to each line in the scanning direction. Here, the load applied to each line is the sum of the magnitudes of the video signals (that is, the load applied to each pixel) input to each pixel corresponding to the corresponding one line when displaying the image indicated by the video signal on the video display device. It can be said. The correction value setting unit sets a correction value for correcting the video signal for each line based on the load applied for each line calculated by the line load calculator. Here, the setting of the correction value can be performed using, for example, a look-up table in which loads and correction values for each line are previously associated. The total load calculating unit calculates the total load applied to the entire screen when the input image signal is displayed on the screen. In this case, the total load can be, for example, the same value as the sum of loads applied for each one line. The correction value adjusting unit adjusts each correction value for each line based on the correction value for each line set by the correction value setting unit and the total load calculated by the total load calculating unit. Here, the adjustment of each correction value for each line in the correction value adjusting unit makes the gain of the video signal close to 1 when the total load is large, and zeros the gain of the video signal when the total load is small. By close to The video signal correcting unit corrects the video signal for each line based on the correction value for each line adjusted by the correction value adjusting unit. With such a configuration, the video signal can be corrected for each line in the scanning direction based on the input video signal.

The total load calculation unit includes a load calculation unit that calculates the total load, and an adjustment value setting unit that sets an adjustment value for adjusting the correction value for each line based on the calculated total load. The value adjusting unit may adjust each of the correction values for each one line by multiplying each of the correction values for each one line by the adjustment value.

With such a configuration, it is possible to adjust each correction value for each line based on the correction value for each line set by the correction value setting unit and the total load calculated by the total load calculation unit.

The image signal corrector may adjust the brightness of the input video signal by reducing the gain of the input video signal for each line based on the adjusted value for each line.

With this configuration, it is possible to prevent the luminance of the displayed image from being greatly changed even when the load applied to each line is greatly changed as the input image signal is continuously changed greatly.

In addition, the image signal correcting unit may make the gain closer to 1 as the total load is larger, and the gain closer to 0 as the total load is smaller.

This configuration prevents the brightness of the displayed video from being greatly changed even when the load applied to each line is greatly changed as the input video signal is continuously changed greatly, and the brightness can be displayed as high as possible. have.

The apparatus may further include a video signal delay unit for delaying the input video signal in front of the video signal corrector.

By such a configuration, it is possible to prevent the video signal used to derive the correction value adjusted by the correction value adjusting unit and the video signal corrected by the image signal correction unit.

Further, in order to achieve the above object, according to the second aspect of the present invention, calculating the load applied to each line in the scanning direction based on the input video signal, and calculating the load applied to each line Setting a correction value for each line based on the load applied to each line calculated by the step of calculating the total load applied to the entire screen when the input image signal is displayed on the screen; Setting an adjustment value for adjusting the correction value for each line based on the total load calculated in the step of calculating the total load, the correction value for each line and the value based on the adjustment value Adjusting each correction value for each line, and correcting the input video signal based on the correction value for each line adjusted in the adjusting step. It is provided an image correction method.

This method sets a correction value based on the load applied to each line in the scanning direction calculated using the input video signal and the total load applied to the entire screen calculated using the input video signal. Correct the input video signal based on this. By this method, the video signal can be corrected for each line in the scanning direction based on the input video signal.

Further, in order to achieve the above object, according to the third aspect of the present invention, calculating loads per line in the scanning direction based on the input video signal, and based on load calculation results per line Setting a correction value for correcting the video signal for each line, calculating a total load applied to the entire screen when the input video signal is displayed on the screen, and based on the total load. And adjusting a correction value for each line, and correcting the input image signal based on the adjusted correction value for each line. A recording medium can be provided.

With a computer-readable recording medium on which such a program is recorded, the video signal can be corrected for each line in the scanning direction based on the input video signal.

Further, in order to achieve the above object, according to a fourth aspect of the present invention, an image display device for displaying a corrected image by correcting an input image signal, comprising: an image correction unit for correcting the input image signal; A line display calculation unit configured to display an image based on the image signal corrected by the image correction unit, the image correction unit calculating a load applied to each line in a scanning direction based on the input image signal; A correction value setting unit for setting a correction value for correcting an image signal for each line based on a calculation result of the line load calculation unit, and displaying the input image signal on the image display unit based on the input image signal A total load calculating section that calculates a total load on the image display unit at a time; and the total load calculated by the full load calculating section A correction value adjusting unit for adjusting each of the correction values for each line based on the correction value setting unit, and an image signal for correcting the input video signal based on the correction value for each line adjusted by the correction value adjusting unit An image display device having a correction unit is provided.

The video display device includes, for example, an image corrector and an image display unit. The image correction unit includes, for example, a line load calculation unit, a correction value setting unit, a total load calculation unit, a correction value adjustment unit, and a video signal correction unit, and for each line in the scanning direction based on the input video signal. Correct the video signal. The image display unit displays an image based on the image signal corrected by the image corrector. With such a configuration, it is possible to display the corrected video signal for each line in the scanning direction based on the input video signal.

EMBODIMENT OF THE INVENTION Hereinafter, preferred embodiment of this invention is described in detail, referring an accompanying drawing. In the present specification and drawings, redundant descriptions of components having substantially the same functional configuration will be omitted by attaching the same reference numerals.

(Image correction device according to an embodiment of the present invention)

First, an image correction apparatus according to an embodiment of the present invention will be described. 4 is a block diagram showing an image correction device 100 according to an embodiment of the present invention. Hereinafter, a video signal input to the video calibrating apparatus 100 will be described as, for example, a digital signal used for digital broadcasting. However, the present invention is not limited thereto and may be an analog signal used for analog broadcasting.

Referring to FIG. 4, the image correction device 100 according to the embodiment of the present invention includes a line load calculation unit 102, a correction value setting unit 104, a total load calculation unit 106, and a correction value. An adjusting unit 108, a video signal delay unit 110, and a video signal correction unit 112 are provided.

The line load calculation unit 102 calculates the load applied to each line in the scanning direction. Here, the load applied to each line means that the size of the video signal input to each pixel corresponding to the one line when the video indicated by the video signal is displayed on the video display device (not shown in FIG. 4) (that is, the pixel). It can be said that it is the sum total of the loads applied to each). Hereinafter, the load applied to each line will be described in correspondence with the pixels included in the video display device (not shown in FIG. 4) corresponding to the one line.

Here, when the video signal input to the video correction device 100 is a video signal for displaying an image of SD (Standard Definition) resolution, for example, it has 480 lines, and 640 pixels correspond to each line. . In addition, when the video signal displays a color display image, each of the lines corresponds to 640 × 3 = 1920 sub pixels corresponding to red, green, and blue. In addition, when the video signal input to the video correction device 100 is a video signal for displaying an image having a high definition (HD) resolution, for example, it has 1080 lines, and 1920 pixels correspond to each line. In addition, when a video signal displays a color display image, 1920 x 3 = 5760 subpixels correspond to each line.

Therefore, the load required for each line can be expressed by, for example, Equation (1). Here, in Equation 1, Load denotes a load applied to one line, and R1, R2,... And Rn represent gray scale values respectively input to the pixels displaying red color. Similarly, G1, G2,... , Gn represent grayscale values respectively input to the pixels displaying green, and Bn, B2,... And Bn represent gray scale values input to the pixels displaying blue, respectively. n is a natural number and represents the number of pixels which one line has (where a group of red, green, and blue subpixels corresponds to one pixel).

Load = (R1 + R2 +… + Rn) + (G1 + G2 +… + Gn) + (B1 + B2 +… + Bn)

In addition, when the gray level of the video signal input to the video correction device 100 is expressed by, for example, 8 bits, the load minimum value LoadMin applied for each line is expressed as shown in Equation 2, The maximum load LoadMax applied to each line is expressed by Equation 3 below.

LoadMin = 0 × n × 3 = 0

LoadMax = 256 × n × 3 = 768n

Here, Equation 2 shows a case in which all pixels corresponding to one line display black (gradation value is 0), and Equation 3 indicates that all pixels corresponding to one line are white (gray value value is 256). Indicates when is displayed.

The correction value setting unit 104 sets a correction value for correcting the image signal for each line based on the load applied for each line calculated by the line load calculation unit 102. Here, the setting of the correction value can be performed using, for example, a lookup table in which loads and correction values for each line are previously associated with each other.

As shown in equations (2) and (3), as the load value increases, the load applied to each line also increases. Here, for example, in the case where the load applied to each line is greatly changed due to the continuous change of the input image signal, the value of the control voltage applied to the pixel by the image display device (not shown in FIG. 4) becomes large and the luminance is increased. The phenomenon may rise. Such a phenomenon is particularly preferable when the load applied to each line suddenly becomes lighter, which leads to an increase in power consumption in an image display device (not shown in FIG. 4) or acceleration of a deterioration rate of pixels. It is not. Therefore, in order to minimize the increase in power consumption even if the luminance rises, the lookup table may set, for example, a correction value for lowering the gain of the video signal as the load per line decreases. Can be. It goes without saying that the correspondence between the load and the correction value for each line held in the lookup table is not limited to the above.

Further, the correction value for each line set by the correction value setting unit 104 is held in the storage means of the correction value setting unit 104, for example. Here, as the storage means of the correction value setting unit 104, for example, a magnetic recording medium such as a hard disk or a magnetic tape, a flash memory, a magnetoresistive random access memory (MRAM), and the like. Non-volatile memory, such as FeRAM (Ferroelectric Random Access Memory), Phase Change Random Access Memory (PRAM), and a magneto-optical disk, but are not limited to the above. The retention of the correction value for each line is not limited to the above, for example, the image correction apparatus 100 is provided with a storage unit (not shown) and is set by the correction value setting unit 104 in this storage unit. It is also possible to hold a correction value for each line.

The total load calculator 106 includes a load calculator 114 and an adjustment value setting unit 116.

The load calculation unit 114 calculates the total load (LoadTotal) applied to the entire screen when displaying the image indicated by the input video signal on the screen as a display unit included in the video display device (not shown in FIG. 4). Here, the total load LoadTotal may be represented by, for example, Equation 4. m and p are natural numbers, and p = 480 when the video signal is a video signal displaying an image of SD resolution. Similarly, when the video signal is a video signal for displaying an image of HD resolution, p = 1080.

Here, the total load LoadTotal may be, for example, the same value as the sum of the loads applied to each line shown in equation (1). As shown in Equation 4, the method of calculating the total load LoadTotal may add up the loads applied to each line, and the entire screen of the image display apparatus (not shown in FIG. 4) may be based on the input image signal. Although the load applied to each of the pixels to be configured can be summed and calculated, the method of calculating the total load is not limited to the above.

The adjustment value setting unit 116 sets an adjustment value for adjusting the correction value for each line based on the total load calculated by the load calculation unit 114. Here, the setting of the adjustment value can be performed using, for example, a look-up table in which the total load and the adjustment value are previously associated. Here, the lookup table may set, for example, an adjustment value for increasing the gain of the video signal as the total load increases.

As described above, the phenomenon in which the luminance rises when the load applied to each line is greatly changed is particularly likely to occur when the load on each line suddenly becomes light. Therefore, when the total load calculated by the load calculating section 114 is large, that is, when it is estimated that the load on each line is large, the adjustment value is set so that the drop of the gain lowered by the correction value is minimized. By setting the correspondence relationship between the total load and the adjustment value held in the lookup table as described above, the increase in power consumption can be minimized, and the brightness is as high as possible, so that a high quality image can be displayed in the video display device (FIG. 4). Not shown).

As described above, the total load calculating section 106 includes the load calculating section 114 and the adjustment value setting section 116 to calculate the total load applied to the entire screen and to adjust the correction value for each line. You can set the value.

In addition, the adjustment value set by the adjustment value setting part 116 is hold | maintained in the memory means which the adjustment value setting part 116 has, for example. Here, the storage means included in the adjustment value setting unit 116 may include, for example, a magnetic recording medium such as a hard disk, a nonvolatile memory such as a flash memory, and the like, but is not limited to the above. The holding of the entire value is not limited to the above, and for example, the image adjusting device 100 includes a storage unit (not shown), and this storage unit holds the entire value set by the adjustment value setting unit 116. It may be.

The correction value adjusting unit 108 adjusts each of the correction values for each line based on the correction value for each line set by the correction value setting unit 104 and the adjustment value set by the adjustment value setting unit 116. . Here, the adjustment of each correction value for each line in the correction value adjusting unit 108 is, for example, the correction value adjusting unit 108 corrects for each line from the storage means of the correction value setting unit 104. The reading can be performed by reading the value and reading the adjustment value from the storage means of the adjustment value setting unit 116 and multiplying the adjustment value by each of the correction values for each line, but not limited to the above. For example, the correction value and the adjustment value for each line can be read from a storage unit (not shown) included in the image adjustment device 100. The adjustment of each correction value for each line in the correction value adjusting unit 108 is not limited to multiplying each of the correction values for each line by the adjustment value, for example, the adjustment value for each of the correction values for each line. Needless to say, I can add.

In addition, the correction value for each line adjusted by the correction value adjusting unit 108 is stored in, for example, the storage means of the correction value adjusting unit 108. Here, the storage means included in the correction value adjusting unit 108 may be, for example, a magnetic recording medium such as a hard disk or a nonvolatile memory such as a flash memory, but is not limited to the above. The retention of the correction value for each adjusted line is not limited to the above, for example, the image adjusting device 100 includes a storage unit (not shown), and the storage unit is adjusted by the correction value adjusting unit 108. It is also possible to hold a correction value for each line.

The image signal delay unit 110 delays an image signal input to the image signal correcting apparatus 100. Since the image signal correction apparatus 100 includes the image signal delay unit 110, the image signal used to derive the correction value adjusted by the correction value adjusting unit 108, and the image signal corrected using the correction value are You can prevent anything else. The video signal delay unit 110 may be configured using, for example, a memory such as a random access memory (RAM) or a shift register, but is not limited thereto.

The video signal correction unit 112 is, for example, multiplying the video signal delayed by the video signal delay unit 110 by the correction value for each line adjusted by the correction value adjusting unit 108 for each line. Correct the video signal. The correction of the image signal in the image signal correction unit 112 is not limited to multiplying the correction value of each line by the image signal by one line. For example, the correction value of each image line is corrected by one line. You can also add

5 is a diagram for explaining correction of an image signal in the image correction device 100 according to the embodiment of the present invention. In Fig. 5, the load ratio of one line is taken on the horizontal axis and the gain of the video signal is shown on the vertical axis. As described with reference to FIG. 4, the image correction apparatus 100 sets a correction value for each line based on the input video signal, and sets the correction value according to the total load based on the input video signal. Adjust the correction value for each line. Therefore, the image correction apparatus 100 is the same as the image correction apparatus according to the related art shown in FIG. 3, and the image signal inputted without changing the validity and the invalidity of the image signal before and after the predetermined threshold a is changed. The video signal can be corrected accordingly. Therefore, in the image correction device 100 according to the embodiment of the present invention, the luminance difference due to the correction of the video signal does not occur.

As described above, in the image correction device 100 according to the embodiment of the present invention, the correction value setting unit 104 corrects the correction value for each line based on the load applied for each line calculated by the line load calculation unit 102. In addition, the total load calculation unit 106 sets an adjustment value for adjusting the correction value for each one line. The correction value adjusting unit 108 adjusts the correction value for each line based on the correction value for each line and the adjustment value, and the image signal correction unit 112 adjusts the correction value for each line based on the adjusted correction value. The input video signal is corrected for each line. Therefore, the image correcting apparatus 100 according to the embodiment of the present invention may correct the image signal for each line in the scanning direction based on the input image signal.

In addition, the image correcting apparatus 100 according to the exemplary embodiment of the present invention may correct the image signal based on the correction value according to the image signal inputted by the image signal correcting unit 112. Accordingly, in the image correcting apparatus 100 according to the embodiment of the present invention, the correction of the video signal is not invalidated. For example, the image display apparatus is corrected by the corrected video signal output from the image correcting apparatus 100. The luminance difference resulting from the correction of the image signal in the image correction device 100 does not occur in the displayed image.

Furthermore, in the image correction apparatus 100 according to the embodiment of the present invention, when the total load is large, that is, when the load applied to each line is estimated to be large, the drop width of the gain that the adjustment value setting unit 116 lowers according to the correction value is decreased. Set the adjustment value to this minimum. Therefore, even when the video signal input to the video correction device 100 continuously changes greatly, the video correction device 100 consumes the video display device displaying the video signal output from the video correction device 100. The increase in power can be minimized, and the high quality image can be displayed by increasing the luminance as much as possible.

In addition, in the embodiment of the present invention, the image correction device 100 has been described and described. However, the embodiment of the present invention is not limited to this embodiment, and for example, a self-luminous image display device such as a PDP, an OLED display, or an FED. The present invention can be applied to various video display devices such as a backlight type video display device such as an LCD. Application to the video display device will be described later.

 (Recording medium in which a program about correcting an image signal is recorded)

A video signal is recorded for each line in the scanning direction on the basis of the input video signal by a computer-readable recording medium on which a program for causing the video signal correction apparatus according to the embodiment of the present invention to function as a computer is recorded. You can correct it.

 (Image signal correction method)

Next, a video signal correction method according to an embodiment of the present invention will be described. 6 is a flowchart illustrating an image correction method according to an embodiment of the present invention.

First, based on the input video signal, a correction value for each line and an adjustment value for adjusting the correction value for each one line for each line are set (S100). Hereinafter, the processing performed in step S100 will be described in more detail.

 [Process 1 in Step S100]

The total load is calculated based on the input video signal (S102). Here, the total load may add up the load applied to each line, or may be calculated by adding up the load applied to each pixel constituting the entire screen of the image display apparatus.

The adjustment value is set based on the total load calculated in step S102 (S104). The setting of the adjustment value in step S104 can be performed, for example, using a lookup table in which the total load and the adjustment value are previously associated one-to-one.

 [Process 2 in Step S100]

The load applied to one line is calculated based on the input video signal (S106). Here, the video signal input in step S106 is the same signal as the video signal input in step S102. In addition, the load for each line can be calculated by summing the loads applied to the pixels on one scan line of the screen of the video display device, for example.

Based on the load applied to each line calculated in step S106, the correction value of the corresponding one line is set (S108). The setting of the correction value in step S108 can be performed, for example, using a lookup table in which the load applied to each line and the correction value are previously associated one-to-one.

If the correction value for each line is set in step S108, it is determined whether or not the correction value is set for all the lines (S110). Here, the determination in step S110 can be performed, for example, by comparing the set number of correction values with the number of lines of the video signal. For example, if the video signal is a video signal with SD resolution, it can be determined whether or not the number of correction values is set to 480. If the video signal is a video signal with HD resolution, the number of correction values is 1080. It can be determined whether or not it is set.

In step S110, when it is determined that the correction value is not set in all the lines, the line for calculating the load is changed (S112), and the processes of steps S106 to S110 are repeated.

As described above, in step S100, processing for setting the correction value for each line (steps S106 to 112) and for setting the adjustment value for adjusting the correction value for each one line for each line (steps S102 to 104). Is largely divided into two processes. Here, the processing for setting the correction value for each line (steps S106 to 112) and the processing for setting the adjustment value (steps S102 to 104) can be performed independently and simultaneously, and the processing in step S100 It goes without saying that it is not limited to being done independently and simultaneously.

When it is determined in step S110 that the correction values are set in all the lines, each of the correction values set in one line is adjusted based on the correction value set in one line in step S108 and the adjustment value set in step S104 ( S114). Here, the adjustment of the correction value for each line in step S114 can be performed, for example, by multiplying each of the correction values for each line by the adjustment value.

The input image signal is corrected for each line using the correction value adjusted for each line in step S114 (S116).

As described above, in the video signal correction method according to the embodiment of the present invention, the correction value for each line is set based on the input video signal, and further, by the adjustment value according to the total load based on the input video signal. Adjust the correction value for each line. Therefore, the video signal correction method according to the embodiment of the present invention can correct the video signal for each line in the scanning direction based on the input video signal.

 (Video Display Device According to Embodiment of the Present Invention)

Next, the video display device to which the video signal correction device according to the embodiment of the present invention shown in FIG. 4 is applied will be described. 7 is a block diagram illustrating a video display device 200 according to an embodiment of the present invention.

Referring to FIG. 7, an image display device 200 according to an embodiment of the present invention includes an image corrector 202 and an image display unit 204. Here, the image correcting unit 202 has the same configuration as the video signal correcting apparatus 100 according to the embodiment of the present invention shown in FIG. 4, and outputs an image signal for each line in the scanning direction based on the input video signal. Correct.

The video display unit 204 includes a display unit 206, a row driver 208, a column driver 210, a power supply unit 212, and a controller 214.

The display unit 206 includes a plurality of pixels arranged in a matrix. For example, when the display unit displaying an image having an SD resolution has at least 640 × 480 = 307200 (data line × scanning line) pixels, and the pixel is composed of red, green, and blue subpixels for color display, 640 x 480 x 3 = 921600 (the number of data lines x scanning lines x subpixels). Similarly, for example, the display unit displaying an image having an HD resolution has 1920x1080 pixels, and in the case of color display, it has 1920x1080x3 subpixels.

The row driver 208 and the column driver 210 emit light by applying a voltage to the plurality of pixels of the display unit 206. Here, the row driver 208 and the column driver 210 apply a voltage (scan signal) for determining the ON / OFF of the pixel and apply a voltage (video signal) according to the image displayed by the other. Play a role. In addition, as a driving method of the row driver 208 and the column driver 210, for example, a dot sequential drive scanning method that emits light for each pixel arranged in the matrix shape, and the pixels arranged in the matrix shape are used. And a line sequential drive scanning method for emitting light for every column, and a surface sequential drive scanning method for emitting all pixels arranged in the matrix form. Although the image display apparatus 200 according to the exemplary embodiment of the present invention illustrated in FIG. 7 includes two driving units, a row driver 208 and a column driver 210, an image display apparatus according to an exemplary embodiment of the present invention is described below. It goes without saying that it can be configured by my drive unit.

The power supply unit 212 supplies power to the row driver 208 and the column driver 210, and a voltage is applied to the row driver 208 and the column driver 210. In addition, the magnitude of the voltage applied by the power supply unit 212 to the row driver 208 and the column driver 210 may vary according to the image signal corrected by the image corrector 202.

The controller 214 includes, for example, a central processing unit (CPU) or the like capable of controlling the entire image display apparatus 200, and the row driver 208 according to the image signal corrected by the image corrector 202. And a control signal for applying a voltage for determining the ON / OFF of the pixel to the pixel, and a video signal to the other of the column driver 204. In addition, the controller 214 controls the supply of power to the row driver 208 and the column driver 210 by the power supply 212 according to the image signal corrected by the image corrector 202.

As described above, the image display apparatus 200 according to the embodiment of the present invention corrects an image signal inputted by the image correcting unit 202 corresponding to the image correcting apparatus 100 according to the embodiment of the present invention, and An image may be displayed based on the corrected image signal.

In addition, since the image display device 200 according to the embodiment of the present invention includes the image correcting unit 202, the video signal can be corrected based on the correction value according to the input video signal. There is no invalidity, and the luminance difference due to the correction of the image signal does not occur in the image displayed on the display unit 206.

Furthermore, the image display device 200 according to the embodiment of the present invention includes an image correcting unit 202, so that an image to be input when the total load on the entire pixel (the whole screen) constituting the display unit 206 is large. The corrected video signal can be displayed to minimize the drop in gain of the signal. Therefore, even when the video signal input to the video display device 200 continuously changes greatly, the increase in power consumption of the video display device 200 can be minimized, and the brightness is as high as possible. Can display the image.

In addition, in the embodiment of the present invention, the video display device 200 has been described and described, but the embodiment of the present invention is not limited to such a form, for example, a self-luminous video display device such as a PDP, an OLED display, an FED, Alternatively, the present invention can be applied to various image display devices such as a backlight type image display device such as an LCD. Moreover, embodiment of this invention is applicable to the receiver which receives a television broadcast.

As mentioned above, although preferred embodiment of this invention was described referring an accompanying drawing, it cannot be overemphasized that this invention is not limited to the said example. It will be apparent to those skilled in the art that various modifications or variations can be made within the scope of the claims, and they are naturally understood to belong to the technical scope of the present invention.

For example, in the image correction apparatus 100 according to the embodiment of the present invention illustrated in FIG. 4, the input image signal is a digital signal. However, the image correction apparatus according to the embodiment of the present invention is not limited thereto. For example, an analog-to-digital converter (A / D converter) may be provided, and the input analog signal (video signal) may be converted into a digital signal to process the converted video signal. Even in such a configuration, similarly to the image correction apparatus 100 according to the embodiment of the present invention, the video signal can be corrected for each line in the scanning direction based on the input video signal. In addition, the video correction device according to the embodiment of the present invention includes an analog signal input by configuring each component with an analog circuit, for example, by configuring an image signal delay unit with an integrator using an operational amplifier. It is also possible to process the (video signal) as it is.

In addition, although the image display apparatus 200 according to the embodiment of the present invention illustrated in FIG. 7 includes an image corrector 202 and an image display 204, the image display apparatus 200 is not limited thereto. 202 and the control unit 214 included in the video display unit 204 may be integrated. Even in such a configuration, the controller can correct the input video signal and control the column driver, the row driver, the power supply, and the like based on the corrected video signal. Thus, the video display device 200 according to the embodiment of the present invention. As shown in FIG. 2, the image may be displayed based on the corrected image signal.

It is to be understood that the above-described configuration can be easily changed by those skilled in the art and falls within the equivalent scope of the present invention.

According to the present invention, the video signal can be corrected for each line in the scanning direction based on the input video signal.

Claims (8)

A line load calculator configured to calculate a load applied to each line in the scanning direction based on the input video signal; A correction value setting unit for setting a correction value for correcting an image signal for each line based on a calculation result of the load calculation unit; A total load calculator configured to calculate a total load on the entire screen when the input video signal is displayed on a screen; A correction value adjusting unit that adjusts each correction value for each line set by the correction value setting unit based on the total load calculated by the total load calculating unit; And a video signal corrector for correcting the input video signal based on the correction value for each line adjusted by the correction value adjuster. The method of claim 1, The total load calculation unit, A load calculator configured to calculate the total load; An adjustment value setting unit for setting an adjustment value for adjusting the correction value for each one line based on the calculated total load; And the correction value adjusting unit adjusts each of the correction values for each one line by multiplying each of the correction values for each one line by the adjustment value. The method according to claim 1 or 2, And the image signal correcting unit adjusts the gain of the input image signal to be smaller for each line based on the adjusted correction value for each line, and adjusts the brightness of the input image signal. . The method of claim 3, The image signal correcting unit makes the gain closer to 1 as the total load is larger, and the gain is closer to 0 as the total load is smaller. The method according to any one of claims 1 to 4, And an image signal delay unit configured to delay the input image signal in front of the image signal correction unit. Calculating a load applied to each line in the scanning direction based on the input video signal; Setting a correction value for each line based on the load applied for each line calculated in the step of calculating the load for each line; Calculating a total load on the entire screen when the input video signal is displayed on the screen; Setting an adjustment value for adjusting the correction value for each line based on the total load calculated in the calculating of the total load; Adjusting each of the correction values for each one line based on the correction value for each one line and the adjustment value; And correcting the input video signal based on the correction value for each line adjusted in the adjusting step. Calculating a load applied to each line in the scanning direction based on the input video signal; Setting a correction value for each line based on a load calculation result for each line; Calculating a total load on the entire screen when the input video signal is displayed on the screen; Adjusting each correction value for each line based on the total load and correcting the input image signal based on the adjusted correction value for each line. A computer-readable recording medium on which a program is recorded. An image display apparatus for correcting an input image signal to display a corrected image. An image corrector configured to correct the input image signal; An image display unit which displays an image based on the image signal corrected by the image correction unit, The image correction unit, A line load calculator configured to calculate a load applied to each line in the scanning direction based on the input video signal; A correction value setting unit for setting a correction value for correcting an image signal for each line based on a calculation result of the line load calculator; A total load calculator configured to calculate an overall load applied to the image display unit when displaying the input image signal on the image display unit based on the input image signal; A correction value adjusting unit that adjusts each correction value for each line set by the correction value setting unit based on the total load calculated by the total load calculating unit; And a video signal corrector for correcting the input video signal based on the correction value for each line adjusted by the correction value adjuster.

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