JP7082905B2 - Display device and TV receiver - Google Patents

Description

The present invention relates to a display device and a television receiving device.

As an example of a conventional liquid crystal display device, the one described in Patent Document 1 below is known. In the liquid crystal display device described in Patent Document 1, a plurality of source drive circuits provided with drive ICs are connected to the peripheral edge of the liquid crystal display panel, and the power supply voltage from the outside is adjacent to the source from the specific source drive circuit. Wiring that is sequentially supplied to the drive circuit and is almost equivalent to the signal wiring from the drive IC to the drive IC adjacent to the drive IC on the downstream side in the voltage supply direction with respect to the drive IC located on the upstream side in the voltage supply direction. Form the wiring for resistance calculation. The drive IC calculates the wiring resistance value by outputting the calculation voltage to one end of the wiring resistance calculation wiring and detecting the voltage at the other end, and calculates the voltage drop value based on the calculated wiring resistance value. , The power supply voltage whose voltage value is raised by the calculated voltage drop value is output to the drive IC on the downstream side.

Japanese Unexamined Patent Publication No. 2005-284026

According to the liquid crystal display device described in Patent Document 1 described above, the voltage drop of the power supply voltage sequentially transmitted is prevented and the malfunction of the drive IC is prevented, so that the display quality can be improved. However, since a dedicated wiring resistance calculation wiring is required to calculate the wiring resistance value, a specially designed FPC is required, the cost tends to be high, and the wiring resistance calculation is performed when high definition is advanced. It may be difficult to secure the wiring placement space.

The present invention has been completed based on the above circumstances, and an object of the present invention is to improve display quality without requiring specially designed parts.

The display device of the present invention includes a display component having a display surface in which a plurality of pixel portions are arranged in a matrix, a display drive unit that sequentially displays and drives the plurality of the pixel portions in a column direction, and a plurality of the pixel portions. A storage unit that stores at least the position information about the column direction in the plane of the display surface and the gradation value of each of the pixel portions whose drive order is the nth and (n + 1) th in the column direction. The display driving unit refers to the gradation value of each of the nth and (n + 1) th pixel portions from the storage unit, and the display driving unit refers to the gradation of the (n + 1) th pixel portion. The first correction process of storing the first corrected gradation value obtained by correcting the value in the storage unit and the gradation value of each of the nth and (n + 1) th pixel units are stored in the storage unit. Based on this, the n-th pixel portion and the (n + 1) th pixel portion are separated into a relatively high-brightness bright pixel portion and a relatively low-brightness dark pixel portion. The light / dark separation process for storing the target gradation values of the obtained bright pixel unit and the dark pixel unit in the storage unit, and the nth and (n + 1) th bright pixels performed after the light / dark separation process. The target gradation value of the unit and the dark pixel unit, and the position information about the column direction in the plane of the display surface in the (n + 1) th bright pixel unit or the dark pixel unit. Execution of the (n + 1) th bright pixel portion or the dark pixel portion obtained by correcting the target gradation value of the (n + 1) th bright pixel portion or the dark pixel portion referred to from the storage unit. At least the second correction process of storing the gradation value in the storage unit is performed.

By doing so, a plurality of pixel portions arranged in a matrix in the surface of the display surface of the display component are sequentially displayed and driven in the column direction by the display drive unit, so that a predetermined image is displayed on the display surface. To. Specifically, when the first correction process is performed by the display drive unit, the gradation value of the (n + 1) th pixel portion is corrected based on the gradation value of each of the nth and (n + 1) th pixel portions in the column direction. The first correction gradation value is obtained. The obtained first correction gradation value is stored in the storage unit. Here, for example, when black (minimum gradation value) or white (maximum gradation value) characters and a background of intermediate gradation values adjacent to the characters are displayed on the display surface, the pixel portion for displaying the characters. Since the gradation difference between the pixel part that displays the background and the pixel part that displays the background becomes large, the display gradation of the pixel part that is adjacent to the pixel part that displays characters and displays the background may deviate from the target value. .. On the other hand, if the above-mentioned first correction process is performed, the display gradation of the pixel portion that is adjacent to the pixel portion that displays characters and displays the background is corrected, so that the value becomes closer to the target value. Therefore, excellent display quality can be obtained.

On the other hand, when the luminance separation processing is performed by the display drive unit, the nth pixel unit and the (n + 1) th pixel are based on the gradation values of the nth and (n + 1) th pixel units stored in the storage unit. The section is separated into a bright pixel section having a relatively high brightness and a dark pixel section having a relatively low brightness. The bright pixel portion and the dark pixel portion are set so that the average gradation of each target gradation value is the average value of the gradation values of the nth and (n + 1) th pixel portions. The target gradation values of the bright pixel portion and the dark pixel portion are stored in the storage unit. As a result, it is possible to display using the average gradation of the bright pixel portion and the dark pixel portion adjacent to each other in the column direction, so that the viewing angle characteristic is excellent.

By the way, when the n-th pixel portion and the (n + 1) th pixel portion adjacent to each other in the column direction are separated into a bright pixel portion and a dark pixel portion by the above-mentioned light-dark separation processing, the difference between the light and dark is actually caused. There is a possibility that the display gradation of is deviated from the target gradation value. In addition, in the pixel section far from the display drive section in the column direction, a voltage drop is more likely to occur than in the pixel section close to the display drive section in the column direction, and the actual display gradation is the target gradation value due to this. There is a possibility of deviation. In that respect, when the second correction process is performed by the display drive unit after the light / dark separation process, the target gradation values of the nth and (n + 1) th bright pixel portions and the dark pixel portions in the column direction and (n + 1) The target gradation value of the (n + 1) th bright pixel portion or the dark pixel portion is corrected and executed based on the position information about the column direction in the plane of the display surface in the second bright pixel portion or the dark pixel portion. A gradation value can be obtained. By driving the (n + 1) th bright pixel portion or the dark pixel portion based on the execution gradation value stored in the storage unit, the difference in brightness between the (n + 1) th dark pixel portion or the dark pixel portion is increased from the nth dark pixel portion or the bright pixel portion. Even if it occurs, the actual display gradation of the (n + 1) th bright pixel portion or the dark pixel portion can be made close to the target gradation value, and excellent display quality can be obtained. Moreover, since the execution gradation value of the (n + 1) th bright pixel portion or the dark pixel portion is corrected according to the position in the column direction, the actual display gradation is the purpose due to the voltage drop. It is less likely that the gradation value will deviate. As a result, the display quality can be improved without the need for specially designed parts as in the past. The above-mentioned "n" is a natural number.

According to the present invention, it is possible to improve the display quality without requiring specially designed parts.

An exploded perspective view showing a schematic configuration of the television receiving device according to the first embodiment of the present invention. Top view of the liquid crystal panel, flexible substrate, and control board constituting the liquid crystal display device included in the television receiver. Schematic cross-sectional view of the liquid crystal panel A plan view showing a wiring configuration in a display area of an array board constituting a liquid crystal panel. Block diagram showing the relationship of the configuration related to the display drive of the liquid crystal panel The figure which shows the processing procedure about the display drive of a liquid crystal panel. The figure which shows the 2nd correction data table stored in the storage part. The figure which shows the 3rd correction data table stored in the storage part. The figure which shows the time change of the potential related to the image signal transmitted to the source wiring. The figure which shows the processing procedure about the display drive of the liquid crystal panel which concerns on Embodiment 2 of this invention. The figure which shows the processing procedure about the display drive of the liquid crystal panel which concerns on Embodiment 3 of this invention. The figure which shows the processing procedure about the display drive of the liquid crystal panel which concerns on Embodiment 4 of this invention.

<Embodiment 1>
Embodiment 1 of the present invention will be described with reference to FIGS. 1 to 9. In this embodiment, the liquid crystal display device 10 will be illustrated. A part of each drawing shows an X-axis, a Y-axis, and a Z-axis, and each axis direction is drawn so as to be the direction shown in each drawing. Further, the upper side shown in FIG. 3 and the like is the front side, and the lower side in the figure is the back side.

As shown in FIG. 1, the television receiving device 10TV according to the present embodiment includes a liquid crystal display device 10 having a substantially horizontally long rectangular shape as a whole, and front and back cabinets 10C1 and 10C2 that accommodate the liquid crystal display device 10 so as to sandwich the liquid crystal display device 10. , A power supply 10P, a tuner (reception unit) 10T for receiving a television signal, and a stand 10S are provided. As shown in FIG. 2, the liquid crystal display device 10 includes a liquid crystal panel (display panel) 11 having a display surface 11DS for displaying an image, and a backlight device (lighting device) that supplies light for display to the liquid crystal panel 11. And, these are integrally held by a frame-shaped bezel (not shown together with the backlight device) or the like. The backlight device is arranged on the back side (rear side) of the liquid crystal panel 11 and imparts an optical effect to a light source (for example, an LED) that emits white light (white light) or light from the light source. It has an optical member that converts it into planar light.

Next, the liquid crystal panel 11 will be described. As shown in FIG. 2, the liquid crystal panel 11 is composed of a display area (active area) AA composed of a central portion of the display surface 11DS and displaying an image, and a display area composed of an outer peripheral side portion of the display surface 11DS. It is divided into a non-display area (non-active area) NAA, which forms a frame shape surrounding the AA and does not display an image. The range surrounded by the alternate long and short dash line in FIG. 2 is the display area AA. The liquid crystal panel 11 is formed by laminating a pair of substantially transparent (translucent) glass substrates 11A and 11B. Of the pair of substrates 11A and 11B, the front side (front side) is the CF substrate (opposing substrate) 11A, and the back side (rear side) is the array substrate (active matrix substrate) 11B. The CF substrate 11A has a short side dimension smaller than the same dimension of the array substrate 11B, and has one short side end portion in the Y-axis direction (upper side shown in FIG. 2) aligned with the array substrate 11B. It is pasted together in a state. Therefore, the short side end portion of the array substrate 11B on the other side (lower side shown in FIG. 2) in the Y-axis direction is the CF substrate non-superimposition portion 11B1 on which the CF substrate 11A does not overlap. The CF board non-superimposition portion 11B1 is mounted on the other end side of the flexible board 21 whose one end side is connected to the control board 22 which is a signal supply source. The flexible substrate 21 is flexible by being provided with a film-like base material made of a synthetic resin material (for example, a polyimide resin or the like), and a large number of drivers 23 are surface-mounted on the base material. Wiring pattern (not shown) is arranged and formed. The control board 22 is arranged on the back side of the backlight device by bending the flexible board 21 in a folded shape from the state shown in FIG. The driver 23 is COF (Chip On Film) mounted on the flexible substrate 21. The driver 23 is composed of an LSI chip having a drive circuit inside, processes various signals transmitted from the control board 22, and outputs them to the liquid crystal panel 11.

As shown in FIG. 3, the liquid crystal panel 11 is a substance (liquid crystal material) that is interposed between the pair of substrates 11A and 11B and both substrates 11A and 11B and whose optical characteristics change with the application of an electric field. ), And a seal extending along the circumferential direction so as to seal around the liquid crystal layer 11C, and the two substrates 11A and 11B are bonded together while maintaining a gap corresponding to the thickness of the liquid crystal layer 11C. A unit (not shown) is provided at least. The liquid crystal panel 11 can display an image in the display area AA by using the light supplied from the backlight device, and the front side thereof is the light emitting side. A polarizing plate 12 is attached to each of the outer surfaces of the substrates 11A and 11B.

Of the two substrates 11A and 11B constituting the liquid crystal panel 11, the front side (front side) is the CF substrate 11A, and the back side (rear side) is the array substrate 11B. As shown in FIGS. 3 and 4, a TFT (Thin Film Transistor:), which is a switching element, is located on the inner surface side (liquid crystal layer 11C side, facing surface side of the CF substrate 11A) of the display region AA of the array substrate 11B. A large number of display elements (13) and pixel electrodes 14 are provided side by side in a matrix (matrix) along the X-axis direction (row direction) and the Y-axis direction (column direction), and the TFT 13 and the pixel electrodes 14 are provided. A grid-shaped gate wiring (scanning wiring) 15 and a source wiring (signal wiring, data wiring) 16 are arranged so as to surround the periphery. The gate wiring 15 extends substantially linearly along the X-axis direction and transmits a scanning signal, whereas the source wiring 16 extends substantially linearly along the Y-axis direction and is an image. Transmit a signal. The gate wiring 15 is connected to the gate electrode of the TFT 13, and the source wiring 16 is connected to the source electrode of the TFT 13, whereas the pixel electrode 14 is connected to the drain electrode of the TFT 13. Then, the TFT 13 is driven by supplying a scanning signal from the gate wiring 15, and by supplying the image signal supplied to the source wiring 16 to the pixel electrode 14, the pixel electrode 14 is charged to a potential based on the image signal. do. The pixel electrode 14 is arranged in a substantially rectangular region surrounded by the gate wiring 15 and the source wiring 16 from a transparent electrode film such as ITO (Indium Tin Oxide) or ZnO (Zinc Oxide). Become. As described above, a large number of pixel electrodes 14 are arranged side by side along the X-axis direction and the Y-axis direction. Of these, a large number of pixel electrodes 14 are arranged linearly along the Y-axis direction. The common source wiring 16 is connected via the TFT 13. Therefore, the pixel electrode 14 group forming a row side by side along the Y-axis direction receives the image signal from the common source wiring 16.

On the other hand, as shown in FIG. 3, a large number of color filters 17 are arranged in a matrix on the inner surface side of the display area AA of the CF substrate 11A at positions facing each pixel electrode 14 on the array substrate 11B side. They are installed side by side. In the color filter 17, those exhibiting three colors of red, green, and blue (R, G, B) are repeatedly arranged side by side in a predetermined order. The color filter 17 of each color selectively transmits light in a specific wavelength range related to each color. That is, the red color filter (red color filter) 17 emits light in the red wavelength region, and the green color filter (green color filter) 17 transfers light in the green wavelength region to a blue color filter (blue color filter). ) 17 selectively transmits light in the blue wavelength region. A grid-like light-shielding layer (black matrix) 18 for preventing color mixing is formed between the color filters 17. The light-shielding layer 18 is arranged so as to be superposed on the gate wiring 15 and the source wiring 16 described above in a plan view. On the surface of the color filter 17 and the light-shielding layer 18, a solid facing electrode 19 facing the pixel electrode 14 on the array substrate 11B side is provided. The counter electrode 19 is always maintained at a constant reference potential. Further, on the inner surface side of both substrates 11A and 11B, an alignment film 20 for orienting the liquid crystal molecules contained in the liquid crystal layer 11C is formed.

In the liquid crystal panel 11, as shown in FIG. 3, a color filter 17 and a pixel electrode 14 facing the color filter 17 constitute a pixel portion PX. The pixel unit PX exhibits a display color corresponding to the color exhibited by the color filter 17. Specifically, the one having the red color filter 17 is the red pixel portion (red pixel portion) PX having the red display color, and the one having the green color filter 17 is the green display color. The pixel portion (green pixel portion) PX, and the one having the blue color filter 17 is the blue pixel portion (blue pixel portion) PX whose display color is blue. In FIG. 2, the red color filter 17 and the pixel portion PX are referred to as “R”, the green color filter 17 and the pixel portion PX are referred to as “G”, and the blue color filter 17 and the pixel portion PX are referred to as “B”. , Each is shown. The red, green, and blue pixel portions PX are repeatedly arranged side by side along the X-axis direction (row direction), and those of the same color are continuously arranged along the Y-axis direction (column direction). It is arranged in. As a result, a large number of pixel portions PX exhibiting different colors are arranged in a matrix on the liquid crystal panel 11. In the liquid crystal panel 11, display pixels capable of displaying colors having a predetermined gradation are configured by the pixel portions PX of three colors of red, green, and blue adjacent to each other along the Y-axis direction. Each pixel electrode 14 constituting the pixel portion PX of each color is charged to a potential based on an image signal supplied from the source wiring 16 by driving the connected TFT 13, and the potential difference between the potential and the reference potential of the counter electrode 19 Based on this, the orientation state of the liquid crystal layer 11C in the pixel portion PX of each color changes, so that the amount of transmitted light of the liquid crystal panel 11, that is, the display gradation is individually controlled for each pixel portion PX of each color. Each gate wiring 15 and each source wiring 16 connected to each TFT 13 has a display drive unit 24 (see FIG. 2) provided on the control board 22 (see FIG. 2) via a flexible board 21 connected to the end of the array board 11B. A scanning signal and an image signal are supplied from (see FIG. 5), respectively. The display drive unit 24 sequentially drives each TFT 13 by sequentially supplying scanning signals to each gate wiring 15 from the upper side shown in FIG. 4, and for example, according to the display gradation of each pixel unit PX. An image signal having 256 gradations having a gradation value of 0 to 255 is supplied to each source wiring 16.

Here, a specific display drive in the liquid crystal panel 11 will be described. As shown in FIG. 4, the display drive unit 24 provided on the control board 22 has a plurality of pixel units PX, a relatively high-brightness (bright) bright pixel unit HPX, and a relatively low-brightness (dark) darkness. The display is driven so as to include the pixel unit LPX. Specifically, in the display drive unit 24, the pixel units PX adjacent to each other in the Y-axis direction are the bright pixel unit HPX and the dark pixel unit LPX, and the pixel units PX adjacent to each other in the X-axis direction are the bright pixel unit HPX and the dark pixel unit. The display is driven so as to be LPX. Then, the display drive unit 24 drives the display so that the average gradation between the display gradation of the bright pixel unit HPX adjacent to each other in the Y-axis direction and the display gradation of the dark pixel unit LPX becomes the target display gradation. ing. As a result, the brightness perceived by the user is equalized regardless of the angle at which the display surface 11DS of the liquid crystal panel 11 is visually recognized, and the viewing angle is corrected. Can be planned. Further, the display drive unit 24 periodically reverses the polarity related to the image signal for each pixel unit PX, thereby preventing deterioration of the liquid crystal layer 11C.

By the way, when the display drive is performed in which the pixel portions PX adjacent to each other in the Y-axis direction are the bright pixel portion HPX and the dark pixel portion LPX as described above, it is caused by the gradation difference between the bright pixel portion HPX and the dark pixel portion LPX. Therefore, the actual display gradation may deviate from the target gradation value. For example, if a low-gradation image signal is supplied to the dark pixel portion LPX immediately after the high-gradation image signal is supplied to the bright pixel portion HPX by the source wiring 16, the actual display gradation in the dark pixel portion LPX is the target scale. It tends to be higher than the bid price. On the contrary, if a high-gradation image signal is supplied to the bright pixel portion HPX immediately after the low-gradation image signal is supplied to the dark pixel portion LPX by the source wiring 16, the actual display gradation in the bright pixel portion HPX is the purpose. It tends to be lower than the gradation value. In addition, the source wiring 16 transmits the image signal output from the driver 23 mounted on the flexible board 21, and the pixels arranged farther from the driver 23 than the pixel portion PX arranged closer to the driver 23. In the part PX, a voltage drop due to wiring resistance may occur. That is, the longer the wiring length of the source wiring 16 from the driver 23 to the pixel portion PX, the greater the influence of the voltage drop, and due to this, the actual display gradation in the pixel portion PX is larger than the target gradation value. It tends to be low. The lower pixel portion PX shown in FIG. 4 is arranged close to the driver 23, and the upper pixel portion PX shown in FIG. 4 is arranged far from the driver 23.

Therefore, as shown in FIG. 5, the liquid crystal display device 10 according to the present embodiment sequentially performs the processes shown in FIG. 6 by the display drive unit 24 and the storage unit 25 provided on the control board 22. The display of the pixel unit PX is driven. By using the information stored in the storage unit 25, the display drive unit 24 uses the digital unevenness correction process 30, the digital gamma process 31, the overshoot process 32, and the first correction process 33, as shown in FIG. , The light / dark separation process 34, the second correction process 35, and the analog gamma process 36 are sequentially performed. Of these, in the digital unevenness correction processing 30, for example, the gradation value is increased at a portion where the gradation value (luminance) is extremely low based on the brightness distribution information included in the television broadcast wave, and the gradation value is extremely high. Corrections are made to lower the gradation value for the points. In the digital gamma processing 31, for example, digital data related to a television broadcast wave is converted using a gamma curve suitable for the display characteristics of the liquid crystal panel 11. In the overshoot processing 32, the overshoot characteristic is corrected so that the voltage at the rising edge of the image signal supplied to the pixel unit PX is pulsedly excessive. As a result, the response speed of the liquid crystal molecules contained in the liquid crystal layer 11C becomes faster especially at the time of halftone display, and the moving image display performance becomes excellent. Although the details of the first correction process 33 will be described later, when the image displayed on the display surface 11DS contains characters, the display floor of the pixel unit PX that is adjacent to the pixel unit PX that displays the characters and displays the background. The key is corrected. This can prevent bleeding around the characters. In the light / dark separation process 34, although details will be described later, two pixel portions PX adjacent to each other in the Y-axis direction are separated into a bright pixel portion HPX and a dark pixel portion LPX. The second correction process 35, which will be described in detail later, corrects and executes the target gradation values in the bright pixel portion HPX and the dark pixel portion LPX adjacent to each other in the Y-axis direction based on the position information in the Y-axis direction. The gradation value is obtained. In the analog gamma processing 36, the execution gradation value of each pixel portion PX obtained through the second correction processing 35 is converted into a voltage value which is analog data, that is, an image signal actually supplied to the source wiring 16.

Subsequently, the first correction process 33, the light / dark separation process 34, and the second correction process 35 will be described in detail. First, in the storage unit 25 shown in FIG. 5, position information about the Y-axis direction in a large number of pixel units PX arranged along the Y-axis direction in the display area AA and two adjacent pixels in the Y-axis direction are stored. At least the gradation value by the set of the unit PX is stored, and the display driving unit 24 sequentially displays and drives the pixel unit PX in the Y-axis direction based on this information. In the first correction process 33, the display drive unit 24 is the second pixel unit PX of the nth and (n + 1) th pixels counted from the upper side (drive start side by the display drive unit 24) shown in FIG. 4 in the Y-axis direction. The gradation value and the position information about the X-axis direction and the Y-axis direction in the plane of the display surface 11DS regarding these two pixel units PX are referred from the storage unit 25. In the first correction process 33, the display driving unit is the floor of the (n + 1) th pixel unit PX based on the gradation values of the nth and (n + 1) th pixel units PX and the above-mentioned position information. The adjustment value is converted into a first correction gradation value, and the converted first correction gradation value is stored in the storage unit 25. By repeating this, the first correction gradation value of all the pixel units PX is stored in the storage unit 25. By doing so, for example, when black (minimum gradation value) or white (maximum gradation value) characters and a background of intermediate gradation values adjacent to the characters are displayed on the display surface 11DS, the characters are displayed. Even if the gradation difference between the pixel part PX to be displayed and the pixel part PX to display the background is large, the display gradation of the pixel part PX that is adjacent to the pixel part PX that displays characters and displays the background. Can be corrected appropriately. As a result, the pixel portion PX adjacent to the pixel portion PX and displaying the background can be displayed and driven with a gradation close to the target gradation, and excellent display quality can be obtained.

In the luminance separation processing 34, the first correction gradation value (gradation value after the first correction processing 33) stored in the storage unit 25 is referred to, and the nth pixel unit is based on the first correction gradation value. The PX and the (n + 1) th pixel portion PX are separated into a bright pixel portion HPX having a relatively high brightness and a dark pixel portion LPX having a relatively low brightness. When the nth pixel portion PX becomes the bright pixel portion HPX, the (n + 1) th pixel portion PX becomes the dark pixel portion LPX, and conversely, when the nth pixel portion PX becomes the dark pixel portion LPX, ( The n + 1) th pixel portion PX becomes the bright pixel portion HPX. Specifically, for example, when the first correction gradation value stored in the storage unit 25 is 128 gradations, the target gradation value of the bright pixel unit HPX is 140 gradations, and the target scale of the dark pixel unit LPX. Light and dark separation processing is performed so that the adjustment value has 116 gradations. That is, the bright pixel portion HPX and the dark pixel portion LPX are values obtained by averaging the first correction gradation values of the two pixel portions PX whose target gradation values are the nth and (n + 1) th average gradations. Is set. The target gradation values of the bright pixel unit HPX and the dark pixel unit LPX obtained in the light / dark separation process 34 are stored in the storage unit 25. As a result, it is possible to display using the average gradation of the bright pixel portion HPX and the dark pixel portion LPX adjacent to each other in the Y-axis direction, so that the viewing angle characteristic is excellent.

The second correction process 35 includes the target gradation value of each of the nth and (n + 1) th pixel portions PX (bright pixel portion HPX and dark pixel portion LPX) and the (n + 1) th pixel portion PX (bright pixel portion HPX). Alternatively, the position information about the Y-axis direction in the plane of the display surface 11DS in the dark pixel unit LPX) and the second correction data table (correction data table) are referred to from the storage unit 25. As shown in FIG. 7, the second correction data table serves as a reference for the target gradation value of each of the nth and (n + 1) th pixel portions PX and the execution gradation value in the (n + 1) th pixel portion PX. It describes the relationship with the reference execution gradation value. The reference execution gradation value described in the second correction data table is set with reference to the pixel unit PX at the drive end end position of the display drive unit 24 in the Y-axis direction in the surface of the display surface 11DS. The display drive unit 24 acquires the reference execution gradation value by referring to the second correction data table stored in the storage unit 25. For example, the target gradation value of the nth pixel portion PX (dark pixel portion LPX) is 116 gradations, and the target gradation value of the (n + 1) th pixel portion PX (bright pixel portion HPX) is 140 gradations. In a certain case, 150 gradations described at the intersection of the above two target gradation values in the second correction data table are extracted as the reference execution gradation value.

Subsequently, the display drive unit 24 stores the reference execution gradation value obtained as described above in the third correction data table stored in the storage unit 25 and the (n + 1) th pixel unit PX in the Y-axis direction. It is corrected to the execution gradation value based on the position information about. In the third correction data table, as shown in FIG. 8, a correction coefficient corresponding to the position information in the Y-axis direction in the (n + 1) th pixel portion PX is described. The correction coefficient is individually set for 10 regions from the first region to the tenth region obtained by dividing the display surface 11DS in the Y-axis direction. The first region is on the drive start end side of the display drive unit 24, while the tenth region is on the drive end end side of the display drive unit 24. The correction coefficient is set to the minimum value "0.1" in the first region and the maximum value "1.0" in the tenth region. That is, the correction coefficient described in the third correction data table is set with reference to the pixel unit PX in the tenth region (the position of the drive end end of the display drive unit 24). Then, the display driving unit 24 calculates the difference between the reference execution gradation value extracted from the second correction data table and the target gradation value in the (n + 1) th pixel unit PX, and the second is obtained with respect to the difference. 3 The second correction gradation value is acquired by multiplying the correction coefficients extracted from the correction data table.

Then, the display drive unit 24 acquires the execution gradation value by adding the obtained second correction gradation value to the target gradation value in the (n + 1) th pixel unit PX. For example, when the reference execution gradation value is 150 gradations and the target gradation value in the (n + 1) th pixel portion PX is 140 gradations, 10 gradations are obtained as the difference. When the (n + 1) th pixel portion PX is arranged in the tenth region, 10 gradations are obtained as the second correction gradation value by multiplying the 10 gradations of the difference by the correction coefficient 1.0. Be done. Therefore, by adding the 10 gradations which are the second correction gradation values to the 140 gradations which are the target gradation values in the (n + 1) th pixel portion PX, 150 gradations as the execution gradation value can be obtained. .. On the other hand, when the (n + 1) th pixel portion PX is arranged in the first region, the difference of 10 gradations is multiplied by the correction coefficient 0.1 to obtain 1 as the second correction gradation value. Gradation is obtained. Therefore, by adding 1 gradation which is the second correction gradation value to 140 gradation which is the target gradation value in the (n + 1) th pixel portion PX, 141 gradation is obtained as the execution gradation value. .. The execution gradation value obtained by correcting the target gradation value of the (n + 1) th pixel unit PX in this way is stored in the storage unit 25. After that, in the analog gamma processing 36, the execution gradation value of each pixel unit PX stored in the storage unit 25 is converted into an image signal actually supplied to the source wiring 16. By doing so, the image signal supplied from the source wiring 16 to the TFT 13 becomes a rectangular wave having a steep rising shape and falling shape, as shown by the solid line in FIG. The two-point chain line in FIG. 9 represents the waveform of the image signal when the second correction process 35 is not performed, and the waveform of the image signal obtained by performing the second correction process 35 is higher than this waveform. The dullness is reduced, and the pixel electrode 14 can be charged to an appropriate voltage (gradation value). Thereby, excellent display quality can be obtained.

As described above, the liquid crystal display device (display device) 10 of the present embodiment includes a liquid crystal panel (display component) 11 having a display surface 11DS in which a plurality of pixel portions PX are arranged in a matrix, and a plurality of pixel portions PX. The display drive unit 24 that sequentially displays and drives the display in the column direction, the position information about the column direction in the plane of the display surface 11DS in the plurality of pixel units PX, and the drive order in the column direction are the nth and (n + 1) th. The display drive unit 24 includes a storage unit 25 that stores at least the gradation value of each pixel unit PX of the above, and the display drive unit 24 stores the gradation value of each of the nth and (n + 1) th pixel units PX from the storage unit 25. The first correction process 33 for storing the first correction gradation value obtained by correcting the gradation value of the (n + 1) th pixel unit PX in the storage unit 25, and each of the nth and (n + 1) th pixels. The gradation value of the pixel unit PX is referred from the storage unit 25, and based on this, the nth pixel unit PX and the (n + 1) th pixel unit PX are relatively high-brightness bright pixel unit HPX. The light / dark separation process 34 for storing the target gradation values of the bright pixel section HPX and the dark pixel section LPX obtained separately from the low-brightness dark pixel section LPX in the storage section 25, and the light / dark separation process 34 are performed after the light / dark separation process 34. About the target gradation value of the nth and (n + 1) th bright pixel part HPX and the dark pixel part LPX, and the column direction in the plane of the display surface 11DS in the (n + 1) th bright pixel part HPX or the dark pixel part LPX. The (n + 1) th bright pixel portion HPX or dark pixel obtained by correcting the target gradation value of the (n + 1) th bright pixel portion HPX or the dark pixel portion LPX by referring to the position information of the (n + 1) th bright pixel portion HPX or the dark pixel portion LPX. At least the second correction process 35 for storing the execution gradation value of the unit LPX in the storage unit 25 is performed.

By doing so, a plurality of pixel units PX arranged in a matrix in the surface of the display surface 11DS of the liquid crystal panel 11 are sequentially displayed and driven in the column direction by the display drive unit 24, so that the display surface 11DS is predetermined. Image is displayed. Specifically, when the first correction process 33 is performed by the display drive unit 24, the floor of the (n + 1) th pixel unit PX based on the gradation values of the nth and (n + 1) th pixel unit PX in the column direction. The adjustment value is corrected and the first corrected gradation value is obtained. The obtained first correction gradation value is stored in the storage unit 25. Here, for example, when a black (minimum gradation value) or white (maximum gradation value) character and a background of an intermediate gradation value adjacent to the character are displayed on the display surface 11DS, a pixel for displaying the character. Since the gradation difference between the portion PX and the pixel portion PX that displays the background becomes large, the display gradation of the pixel portion PX that is adjacent to the pixel portion PX that displays characters and displays the background is from the target value. There is a possibility of deviation. On the other hand, if the first correction process 33 described above is performed, the display gradation of the pixel portion PX that is adjacent to the pixel portion PX that displays characters and displays the background is corrected, and is close to the target value. As a result, excellent display quality can be obtained.

On the other hand, when the luminance separation process 34 is performed by the display driving unit 24, the nth pixel unit PX and the nth pixel unit PX based on the gradation values of the nth and (n + 1) th pixel units PX stored in the storage unit 25 ( The n + 1) th pixel portion PX is separated into a bright pixel portion HPX having a relatively high brightness and a dark pixel portion LPX having a relatively low brightness. The bright pixel portion HPX and the dark pixel portion LPX are set so that the average gradation of the respective target gradation values is the average value of the gradation values of the nth and (n + 1) th pixel portions PX. The target gradation values of the bright pixel unit HPX and the dark pixel unit LPX are stored in the storage unit 25. As a result, it is possible to display using the average gradation of the bright pixel portion HPX and the dark pixel portion LPX adjacent to each other in the column direction, so that the viewing angle characteristic is excellent.

By the way, when the nth pixel portion PX and the (n + 1) th pixel portion PX adjacent to each other in the column direction are separated into the bright pixel portion HPX and the dark pixel portion LPX in the above-mentioned light / dark separation processing 34, the difference in light / darkness is obtained. There is a possibility that the actual display gradation deviates from the target gradation value due to the above. In addition, in the pixel unit PX far from the display drive unit 24 in the column direction, a voltage drop is more likely to occur than in the pixel unit PX closer to the display drive unit 24 in the column direction, and the actual display gradation is caused by this. There is a possibility that it deviates from the target gradation value. In that respect, when the second correction process 35 is performed by the display drive unit 24 after the light / dark separation process 34, the target gradation values of the nth and (n + 1) th bright pixel section HPX and the dark pixel section LPX in the column direction are performed. And, based on the position information about the column direction in the plane of the display surface 11DS in the (n + 1) th bright pixel portion HPX or the dark pixel portion LPX, and the (n + 1) th bright pixel portion HPX or the dark pixel portion LPX. The target gradation value of is corrected and the execution gradation value is obtained. The (n + 1) th bright pixel portion HPX or the dark pixel portion LPX is driven based on the execution gradation value stored in the storage unit 25, so that it is between the nth dark pixel portion LPX or the bright pixel portion HPX. Even if there is a difference between light and dark, the actual display gradation of the (n + 1) th bright pixel portion HPX or the dark pixel portion LPX can be made close to the target gradation value, and excellent display quality can be obtained. Moreover, since the execution gradation value of the (n + 1) th bright pixel portion HPX or the dark pixel portion LPX is corrected according to the position in the column direction, the actual display gradation is caused by the voltage drop. Is less likely to deviate from the target gradation value. As a result, the display quality can be improved without the need for specially designed parts as in the past. The above-mentioned "n" is a natural number.

Further, the storage unit 25 has a target gradation value of the nth and (n + 1) th bright pixel unit HPX and the dark pixel unit LPX, and an execution gradation value in the (n + 1) th bright pixel unit HPX or the dark pixel unit LPX. A second correction data table (correction data table) describing the relationship between the reference execution gradation value and the reference execution gradation value of the above is stored, and the display drive unit 24 stores the second correction data table in the storage unit 25 in the second correction process 35. The reference execution gradation value is acquired by referring to the second correction data table, and the reference execution gradation value is obtained based on the position information in the column direction in the (n + 1) th bright pixel portion HPX or the dark pixel portion LPX. Correct to the execution gradation value. In this way, when the second correction process 35 is performed, the display drive unit 24 refers to the second correction data table stored in the storage unit 25, and is the nth and (n + 1) th bright in the column direction. The reference execution gradation value of the (n + 1) th bright pixel portion HPX or the dark pixel portion LPX is acquired based on the target gradation value of the pixel portion HPX and the dark pixel portion LPX. This reference execution gradation value is an execution gradation value in the pixel unit PX arranged at a predetermined position in the column direction, and is a value that serves as a reference for correction based on the position information in the column direction described below. Then, the display driving unit 24 corrects the reference execution gradation value to the execution gradation value based on the position information about the column direction in the (n + 1) th bright pixel unit HPX or the dark pixel unit LPX. Since the reference execution gradation value obtained by referring to the second correction data table is used as described above, the processing can be simplified.

Further, the storage unit 25 stores a correction coefficient according to the position in the column direction in the (n + 1) th bright pixel unit HPX or the dark pixel unit LPX, and the display drive unit 24 stores the correction coefficient in the second correction process 35. Refer to the correction coefficient in the (n + 1) th bright pixel portion HPX or the dark pixel portion LPX from the storage unit 25, and refer to the reference execution gradation value and the target gradation in the (n + 1) th bright pixel portion HPX or the dark pixel portion LPX. The execution gradation value is obtained by adding the second correction gradation value obtained by multiplying the difference from the value by the correction coefficient to the target gradation value in the (n + 1) th bright pixel portion HPX or the dark pixel portion LPX. .. In this way, when the second correction process 35 is performed, the display drive unit 24 has the reference execution gradation value obtained by referring to the second correction data table and the (n + 1) th bright pixel unit HPX or dark. The second correction gradation is obtained by multiplying the difference from the target gradation value in the pixel portion LPX by the correction coefficient corresponding to the position information in the column direction in the (n + 1) th bright pixel portion HPX or the dark pixel portion LPX. Get the value. Then, the display drive unit 24 adds the obtained second correction gradation value and the target gradation value in the (n + 1) th bright pixel unit HPX or the dark pixel unit LPX to the execution gradation value. Is getting.

Further, in the storage unit 25, the reference execution gradation value and the correction coefficient described in the second correction data table are based on the pixel unit PX at the drive end end position of the display drive unit 24 among the plurality of pixel units PX. It is supposed to be. Since the voltage drop that occurs in the pixel unit PX at the drive end end position of the display drive unit 24 is maximum, the deviation between the actual display gradation and the target gradation value due to the voltage drop is also maximum. Since the reference execution gradation value and the correction coefficient described in the second correction data table are based on the pixel portion PX that maximizes the deviation from the target gradation value, the execution gradation value can be obtained with high accuracy. It can be corrected.

Further, the display drive unit 24 performs the light / dark separation process 34 after the first correction process 33. By doing so, the first correction process 33 can be performed prior to the light / dark separation process 34.

Further, the television receiving device 10TV according to the present embodiment includes the liquid crystal display device 10 described above. According to such a television receiving device 10TV, since the display quality of the liquid crystal display device 10 is excellent, it is possible to realize the display of a television image having excellent display quality.

<Embodiment 2>
Embodiment 2 of the present invention will be described with reference to FIG. In the second embodiment, the processing procedure by the display driving unit is changed. It should be noted that overlapping description of the same structure, operation and effect as in the first embodiment will be omitted.

In the present embodiment, as shown in FIG. 10, the display driving unit (not shown) performs the light / dark separation process 134 before the digital unevenness correction process 130, that is, before the first correction process 133. After that, the display drive unit sequentially performs the digital unevenness correction process 130, the digital gamma process 131, and the overshoot process 132, then performs the first correction process 133, and then performs the second correction process 135 and the analog gamma process 136.

As described above, according to the present embodiment, the display driving unit performs the light / dark separation process 134 before the first correction process 133. In this way, the first correction process 133 can be performed after the light / dark separation process 134 is performed.

<Embodiment 3>
Embodiment 3 of the present invention will be described with reference to FIG. In the third embodiment, the processing procedure by the display driving unit is changed from the first embodiment described above. It should be noted that overlapping description of the same structure, operation and effect as in the first embodiment will be omitted.

As shown in FIG. 11, the display drive unit (not shown) according to the present embodiment performs the light / dark separation process 234 after the overshoot process 232 and before the first correction process 233 and the second correction process 235. .. Specifically, in the light / dark separation process 234, the display driving unit refers to the storage unit (not shown) and compares the gradation values of the nth and (n + 1) th pixel units (not shown). To calculate the difference. When the calculated difference is higher than the preset threshold value, the display driving unit does not perform the light / dark separation process 234 for each of the pixel units. That is, each of the nth and (n + 1) th pixel portions whose difference in gradation value exceeds the threshold value is not separated into a bright pixel portion and a dark pixel portion (not shown). On the other hand, when the calculated difference is lower than the threshold value, the display driving unit performs the light / dark separation processing 234 for each of those pixel units. That is, each of the nth and (n + 1) th pixel portions whose difference in gradation value exceeds the threshold value is separated into a bright pixel portion and a dark pixel portion, and the target gradation value is stored in the storage unit. After that, the display drive unit performs the first correction process 233 for the pixel portion where the light / dark separation process 234 is not performed, and the second correction process 235 for the pixel portion where the light / dark separation process 234 is performed. Specifically, the display drive unit makes the first correction for each of the nth and (n + 1) th pixel portions that was not separated into the bright pixel portion and the dark pixel portion in the previous light / dark separation process 234. Process 233 is performed, those gradation values are corrected, and the first corrected gradation value is stored in the storage unit. As a result, when black or white characters are included in the image, it is possible to appropriately correct a large gradation difference that occurs between the characters and the background of the intermediate gradation value. On the other hand, the display drive unit is the first of the nth and (n + 1) th pixel portions, with respect to each pixel portion separated into the bright pixel portion and the dark pixel portion by the previous light / dark separation process 234. The correction process 233 is not performed. As a result, when the image contains a part where characters do not exist (a part having only a background), the first correction is made to the background of the intermediate gradation value (the part where the second correction process 235 is performed). It is possible to avoid processing 233 being performed.

On the other hand, the display drive unit is not separated into the bright pixel portion and the dark pixel portion in the previous light / dark separation processing 234 among the nth and (n + 1) th pixel portions, and the first correction processing 233 is performed. The second correction process 235 is not performed on the pixel portion. As a result, it is possible to avoid performing the second correction process 235 on the portion of the image containing the characters (the portion where the first correction process 233 is performed). On the other hand, the display drive unit is separated into a bright pixel portion and a dark pixel portion by the previous light / dark separation processing 234 among the nth and (n + 1) th pixel portions, and the first correction process 233 is performed. The second correction process 235 is performed on each of the unresolved pixel portions, and the execution gradation value of the bright pixel portion or the dark pixel portion is stored in the storage unit based on the target gradation values of the bright pixel portion and the dark pixel portion. After passing through the first correction process 233 and the second correction process 235, the display drive unit performs analog gamma processing 236.

As described above, according to the present embodiment, the display driving unit compares the gradation values of the nth and (n + 1) th pixel units in the light / dark separation processing 234, and when the difference is higher than the threshold value, n. The th and (n + 1) th pixel portions are not separated into the bright pixel portion and the dark pixel portion, and when the difference is lower than the threshold value, the nth and (n + 1) th pixel portions are divided into the bright pixel portion and the dark pixel portion. The target gradation value is stored separately in the storage unit, and in the first correction process 233, the nth and (n + 1) th pixel portions that are not separated into the bright pixel portion and the dark pixel portion in the light / dark separation process 234 are separated. While the gradation value is corrected and the first corrected gradation value is stored in the storage unit, in the second correction processing 235, the target gradation value of the bright pixel portion and the dark pixel portion separated by the light / dark separation processing 234 is performed. The execution gradation value of the bright pixel portion or the dark pixel portion is stored in the storage unit based on the above. In this way, in the light / dark separation process 234 performed before the first correction process 233, the display drive unit calculates the difference by comparing the gradation values of the nth and (n + 1) th pixel units. .. When the calculated difference is higher than the threshold value, the light / dark separation process 234 is not performed on each of the nth and (n + 1) th pixel portions thereof, and the light / dark pixel portion is not separated into the bright pixel portion and the dark pixel portion. On the other hand, when the calculated difference is lower than the threshold value, the light / dark separation process 234 is performed for each of the nth and (n + 1) th pixel portions, and the target gradation value is obtained by separating into the bright pixel portion and the dark pixel portion. Store in the storage unit. In the first correction process 233, the gradation values of the nth and (n + 1) th pixel portions that were not separated into the bright pixel portion and the dark pixel portion in the light / dark separation processing 234 are corrected to obtain the first correction gradation value. In contrast to storing in the storage unit, in the second correction process 235, the execution gradation of the bright pixel section or the dark pixel section is based on the target gradation values of the bright pixel section and the dark pixel section separated by the light / dark separation process 234. The value is stored in the storage unit.

<Embodiment 4>
Embodiment 4 of the present invention will be described with reference to FIG. In the fourth embodiment, the processing procedure by the display driving unit is changed from the third embodiment described above. It should be noted that the overlapping description of the structure, operation and effect similar to those in the third embodiment will be omitted.

As shown in FIG. 12, the display driving unit (not shown) according to the present embodiment performs the light / dark separation process 334 before the digital unevenness correction process 330, as in the above-described second embodiment. The light / dark separation process 334 is performed in the same manner as in the third embodiment described above. That is, in the light / dark separation process 334, the display driving unit refers to the storage unit (not shown) and compares the gradation values of the nth and (n + 1) th pixel units (not shown) to obtain a difference. calculate. When the calculated difference is higher than the preset threshold value, the display drive unit does not perform the light / dark separation process 334 for each of the pixel portions, but when the difference is lower than the threshold value, each pixel portion thereof. The light / dark separation process 334 is performed. After that, the display drive unit sequentially performs the digital unevenness correction process 330, the digital gamma process 331, and the overshoot process 332, and then performs the first correction process 333 for the pixel unit in which the light / dark separation process 334 is not performed. The second correction process 335 is performed on each of the pixel portions where the process 334 has been performed. The first correction process 333 and the second correction process 335 are the same as those in the third embodiment described above. After that, the display drive unit performs analog gamma processing 336.

<Other embodiments>
The present invention is not limited to the embodiments described above and the drawings, and for example, the following embodiments are also included in the technical scope of the present invention.
(1) In addition to the above-described embodiments, specific numerical values of the reference execution gradation value described in the second correction data table, specific numerical values of the correction coefficient described in the third correction data table, and the like. Can be changed as appropriate.
(2) In each of the above-described embodiments, the reference execution gradation value of the second correction data table and the correction coefficient of the third correction data table are pixels in the tenth region (drive end end position of the display drive unit). The case where the unit is set as a reference is shown. For example, the reference execution gradation value of the second correction data table and the correction coefficient of the third correction data table are set in the first region (drive start end position of the display drive unit). ) May be set as a reference. In addition to this, a setting based on the pixel portion in any of the second to ninth regions can be adopted.
(3) In each of the above-described embodiments, the case where the display surface is divided into 10 regions in the Y-axis direction and the correction coefficient is set in each region is shown, but the specific number of divisions and the correction coefficient of the display surface are shown. The number of settings can be changed as appropriate in addition to 10.
(4) In each of the above embodiments, the case where the driver is COF mounted on the flexible substrate is shown, but the driver is COG (Chip On Glass) mounted on the CF board non-superimposed portion of the array board constituting the liquid crystal panel. It doesn't matter if it is done.
(5) In addition to the above-described embodiments, the specific connection mode of the source wiring to the pixel electrodes (pixel portions) in the liquid crystal panel can be appropriately changed.
(6) In each of the above-described embodiments, the case where the display drive unit and the storage unit are both provided on the control board is shown, but any or all of these may be provided on a component other than the control board. do not have.
(7) In each of the above-described embodiments, the liquid crystal panel and the chassis are placed in a vertical position in which the short side direction thereof coincides with the vertical direction. However, the liquid crystal panel and the chassis have the long side direction in the vertical direction. The present invention also includes a vertically placed state that matches with.
(8) In each of the above-described embodiments, the TFT is used as the switching element of the liquid crystal display device, but it can also be applied to a liquid crystal display device using a switching element other than the TFT (for example, a thin film diode (TFD)). In addition to the liquid crystal display device that displays, it can also be applied to a liquid crystal display device that displays black and white.
(9) In each of the above-described embodiments, the transmissive liquid crystal display device is exemplified, but the present invention can also be applied to a reflective liquid crystal display device and a semi-transmissive liquid crystal display device.
(10) In each of the above-described embodiments, a liquid crystal display device using a liquid crystal panel as a display panel is exemplified, but the present invention can also be applied to a display device using another type of display panel.
(11) In each of the above-described embodiments, a television receiving device provided with a tuner is exemplified, but the present invention can also be applied to a display device not provided with a tuner. Specifically, the present invention can also be applied to a liquid crystal display device used as an electronic signage (digital signage) or an electronic blackboard.
(12) In the above-described first and second embodiments, the case where the first correction process and the second correction process are performed on all the pixel portions is shown, but as in the third and fourth embodiments, the light / dark correction process is performed. It is also possible to perform the first correction process but not perform the second correction process on the pixel portion that does not exist, and to perform the second correction process but not perform the first correction process on the pixel portion that performs the light / dark correction process. be.
(13) In addition to the above-described embodiments, the timing of performing the light / dark separation process can be appropriately changed.

10 ... Liquid crystal display device (display device), 10TV ... TV receiver, 11 ... Liquid crystal panel (display component), 11DS ... Display surface, 24 ... Display drive unit, 25 ... Storage unit, 33, 133, 233, 333 ... 1 Correction process, 34,134,234,334 ... Bright / dark separation process, 35,135,235,335 ... Second correction process, HPX ... Bright pixel section, LPX ... Dark pixel section, PX ... Pixel section

Claims (7)

A display component having a display surface in which a plurality of pixel portions are arranged in a matrix, and
A display drive unit that sequentially displays and drives a plurality of the pixel units in the column direction,
At least the position information about the column direction in the plane of the display surface in the plurality of pixel portions and the gradation value of each of the pixel portions having the nth and (n + 1) th drive orders in the column direction. Equipped with a storage unit to memorize
The display drive unit is
The gradation value and the position information of each of the nth and (n + 1) th pixel portions are referred from the storage unit, and the gradation value of the nth pixel portion is the minimum gradation value or When the gradation value of the (n + 1) th pixel portion is the maximum gradation value and the gradation value of the (n + 1) th pixel portion is an intermediate gradation value, a deviation that may occur in the gradation value of the (n + 1) th pixel portion. The first correction process of storing the first correction gradation value obtained by correcting the above in the storage unit, and
The nth and (n + 1) th pixel portions are referred to from the storage unit, and the nth pixel portion and the (n + 1) th pixel portion are referred to from the storage unit. A light-dark separation process in which the target gradation values of the bright pixel portion and the dark pixel portion obtained by separating into a relatively high-brightness bright pixel portion and a relatively low-brightness dark pixel portion are stored in the storage unit. When,
The target gradation value of the nth and (n + 1) th bright pixel portions and the dark pixel portion, and the (n + 1) th bright pixel portion or the dark pixel, which are performed after the light / dark separation process. With reference to the position information about the column direction in the plane of the display surface in the unit from the storage unit, the target gradation value of the (n + 1) th bright pixel unit or the dark pixel unit can be obtained. At least the second correction process of storing the execution gradation value of the (n + 1) th bright pixel portion or the dark pixel portion obtained by correction in the storage unit is performed .
The storage unit includes the target gradation value of the nth and (n + 1) th bright pixel portions and the dark pixel portion, and the execution in the (n + 1) th bright pixel portion or the dark pixel portion. It stores a correction data table that describes the relationship between the standard execution gradation value, which is the reference of the gradation value, and the standard execution gradation value.
In the second correction process, the display driving unit acquires the reference execution gradation value with reference to the correction data table stored in the storage unit, and the (n + 1) th bright pixel unit or the said. A display device that corrects the target gradation value based on the position information about the column direction in the dark pixel unit and the reference execution gradation value, and obtains the execution gradation value . The storage unit stores a correction coefficient according to the position in the column direction in the (n + 1) th bright pixel unit or the dark pixel unit.
In the second correction process, the display drive unit refers to the correction coefficient in the (n + 1) th bright pixel unit or the dark pixel unit from the storage unit, and refers to the reference execution gradation value and the (n + 1) th. ) The second corrected gradation value obtained by multiplying the difference from the target gradation value in the bright pixel portion or the dark pixel portion by the correction coefficient is the (n + 1) th bright pixel portion or the said. The display device according to claim 1 , wherein the execution gradation value is obtained by adding to the target gradation value in the dark pixel portion. In the storage unit, the reference execution gradation value and the correction coefficient described in the correction data table are based on the pixel unit at the drive end position of the display drive unit among the plurality of pixel units. The display device according to claim 2 . The display device according to any one of claims 1 to 3 , wherein the display drive unit performs the light / dark separation process after the first correction process. The display device according to any one of claims 1 to 3 , wherein the display drive unit performs the light / dark separation process before the first correction process. The display driving unit compares the gradation values of the nth and the (n + 1) th pixel portions in the light / dark separation process, and when the difference is higher than the threshold value, the nth and the (n + 1) th. When each of the second pixel portions is not separated into the bright pixel portion and the dark pixel portion and the difference is lower than the threshold value, the nth and (n + 1) th pixel portions are divided into the bright pixel portion and the (n + 1) th pixel portion. The nth th that was separated into the dark pixel portion and the target gradation value was stored in the storage unit, and was not separated into the bright pixel portion and the dark pixel portion in the light / dark separation processing in the first correction process. And, while the gradation value of each of the (n + 1) th pixel portions is corrected and the first correction gradation value is stored in the storage unit, in the second correction processing, the light / dark separation processing is performed. The display device according to claim 5 , wherein the execution gradation value of the bright pixel unit or the dark pixel unit is stored in the storage unit based on the target gradation value of the separated bright pixel unit and the dark pixel unit. A television receiving device including the display device according to any one of claims 1 to 6 .

Images