JP2016206383A - Liquid crystal display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To properly correct display unevenness irrespective of a visual angle direction.SOLUTION: A liquid crystal display device comprises: a storage part 15 that stores correction data created to make it possible to suppress display unevenness of a liquid crystal display panel 10 displaying an image for measurement in any different visual angle directions on the basis of a result of measuring display characteristics of the liquid crystal display panel 10 from a plurality of visual angle directions; and a correction calculation part 14 that corrects an input video signal on the basis of the correction data.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a technique for making it difficult to visually recognize display unevenness that occurs in a liquid crystal display panel due to manufacturing variations or the like.

  A liquid crystal display device such as a VA (vertical alignment) mode performs gradation display by changing the inclination angle of the liquid crystal molecules with respect to the substrate surface by changing the voltage applied to the pixel.

  For this reason, in the VA mode liquid crystal display device, the viewing angle characteristics change depending on the inclination of the liquid crystal molecules, and therefore, there is a problem that the curve of the gradation luminance ratio differs between when viewed from the front and when viewed from the oblique direction. There is.

  As a technique for improving such a problem, for example, in Patent Document 1, when one subpixel is divided into a plurality of divided subpixels, and each divided subpixel is individually controlled, when viewed from an oblique direction. Techniques for improving the viewing angle characteristics of the above are disclosed.

  Further, in Patent Document 2, in order to correct display unevenness (so-called display spots, etc.) generated in a liquid crystal display panel due to manufacturing variations or the like, a solid image is displayed on the liquid crystal display panel and photographed. A technique for generating correction data for canceling display unevenness based on a result and correcting display image data with the correction data when performing image display is disclosed.

  Note that there is a horizontal electric field type liquid crystal display panel as a liquid crystal display panel with good viewing angle characteristics, but the vertical electric field type has advantages such as good contrast.

JP 2008-287042 A International Publication No. WO2012 / 133890A1 Pamphlet

  By the way, in the VA mode liquid crystal display device, when the display is performed by dividing the sub-pixel into a plurality of divided sub-pixels in order to improve the viewing angle characteristics as in Patent Document 1, the luminance of the sub-pixels is bright divided sub-pixels. This is expressed by the average value of the luminance of the pixel (bright division subpixel) and the luminance of the dark division subpixel (dark division subpixel).

  For this reason, in the configuration in which the subpixel is displayed by being divided into a plurality of divided subpixels as in Patent Document 1, a display screen on which a solid image is displayed as in Patent Document 2 is captured and correction data is obtained. When the generating method is applied, the voltage applied to the subpixel assumed in the input signal at the time of measurement is different from the voltage actually applied to each divided subpixel. For example, when the gradation of the input signal for the subpixel is V52, the gradation of each divided subpixel is set to V48 and V53, respectively.

  Further, the amount of deviation between the gradation that is visually recognized when viewed from the front and the gradation that is visually recognized when viewed from an oblique direction varies depending on the gradation to be displayed. For this reason, in the method of generating correction data by photographing a display screen on which a solid image is displayed, display unevenness when viewed from an oblique direction may not be corrected appropriately.

  For example, display unevenness of gradation V48, gradation V52, and gradation V53 is set to mura_V48, mura_V52, and mura_V53, respectively.

  Originally, the display unevenness value of the gradation V52 is mura_V52, but in a configuration using divided subpixels, it is obtained by measuring by setting the gradation of each divided subpixel to V48 and V53. The display unevenness is (mura_V48 + mura_V53) / 2.

  In this case, the display unevenness when viewed from the front can be corrected with mura_V52 = (mura_V48 + mura_V53) / 2) although it is slightly different from the original value.

  However, as described above, the amount of deviation between the gradation that is visually recognized when viewed from the front and the gradation that is visually recognized when viewed from an oblique direction changes depending on the gradation to be displayed. It has a viewing angle characteristic corresponding to the applied voltage, and the total value of the gradation shift amounts of the divided sub-pixels when viewed from an oblique direction is larger than when viewed from the front. For this reason, the required correction amount differs between when viewed from the front and when viewed from an oblique direction.

  In order to solve this problem, it is only necessary to accurately measure display unevenness for each applied voltage in the case of the bright divided subpixel and the dark divided subpixel. However, the divided subpixel is brighter in a cycle of one frame or less than one frame. Since the divided sub-pixel and the dark divided sub-pixel are switched, the measurement cannot be appropriately performed at the photographing speed (time resolution) of the photographing means such as the currently used photomultiplier or CCD. That is, in a photographing means such as a photomultiplier or a CCD, the received light is converted into electrons and the luminance is measured according to the charging time. For this reason, especially in the case of dark gradation, it takes a long charging time. In addition, since each divided sub-pixel is AC driven, there is a change in luminance between the case where the applied voltage is positive and the case where the applied voltage is negative, and it is necessary to separate the luminance, so higher time resolution is required. .

  The present invention has been made in view of the above problems, and an object of the present invention is to display unevenness regardless of the viewing angle direction in a liquid crystal display panel that performs display by dividing a subpixel into a plurality of divided subpixels. It is to correct appropriately.

  A liquid crystal display device according to an aspect of the present invention includes a liquid crystal display panel including a plurality of picture elements each including a plurality of divided picture elements, and correction data set for each gradation of the input video signal and for each of the divided picture elements. A storage unit for storing; a correction calculation unit that corrects an input video signal based on the correction data to generate a corrected video signal for each of the divided picture elements; and each of the divided picture elements according to the corrected video signal And the correction data includes display unevenness of the liquid crystal display panel based on a result of measuring display characteristics of the liquid crystal display panel displaying a predetermined measurement image from a plurality of viewing angles. The correction data is generated so as to be suppressed even when the viewing angle direction is different.

  According to the above configuration, the display unevenness of the liquid crystal display panel can be suppressed even when the viewing angle directions are different based on the result of measuring the display characteristics of the liquid crystal display panel displaying the measurement image from a plurality of viewing angle directions. Then, the input video signal is corrected using the correction data generated in step S1, and each divided picture element is driven based on the corrected video signal. Thereby, display unevenness can be appropriately corrected regardless of the viewing angle direction.

It is explanatory drawing which shows schematic structure of the liquid crystal display device concerning Embodiment 1 of this invention. 3 is a graph showing gradation luminance ratio characteristics in each divided sub-pixel of the liquid crystal display panel provided in the liquid crystal display device shown in FIG. 1. FIG. 1 shows an example of a gradation luminance ratio curve when the display screen is viewed from an oblique direction when the combination of gradations of each divided sub-pixel with respect to the gradation of the input video signal is optimized in the liquid crystal display device shown in FIG. FIG. It is explanatory drawing which shows an example of the display nonuniformity which arises on the display screen of a liquid crystal display device. (A) is a graph which shows the luminance data of 1 line of x direction among the results of having measured the display luminance value of the display screen shown in FIG. 4 from a specific direction, (b) is a low pass to the measurement result of (a). It is a graph which shows the result of having applied the filter. It is explanatory drawing which shows an example of the measuring method of the measurement performed in order to produce correction data in Embodiment 1 of this invention. It is explanatory drawing which shows schematic structure of the liquid crystal display device concerning Embodiment 2 of this invention. It is sectional drawing of the liquid crystal display panel with which the liquid crystal display device shown in FIG. 7 is equipped. It is explanatory drawing which shows the structure of the TFT glass substrate with which the liquid crystal display panel shown in FIG. 8 is equipped. FIG. 9 is an equivalent circuit diagram of each divided subpixel in the liquid crystal display panel shown in FIG. 8. FIG. 9 is an explanatory diagram illustrating a waveform of a potential applied to each divided subpixel in the liquid crystal display panel illustrated in FIG. 8. It is explanatory drawing which shows the output signal of the gate driver and source driver in the liquid crystal display device shown in FIG. It is explanatory drawing which shows the input / output signal of the source driver in the liquid crystal display device shown in FIG. FIG. 8 is an explanatory diagram illustrating signals handled by the liquid crystal display device illustrated in FIG. 7, where (a) is an input video signal for each sub-pixel input to the sub-pixel dividing unit, and (b) is corrected by the correction calculation unit. The corrected video signal for each divided sub-pixel, (c) shows the output signal from the sub-pixel rearrangement unit to the liquid crystal controller. FIG. 8 is an explanatory diagram showing a relationship between an applied voltage and an alignment direction of liquid crystal molecules in the liquid crystal display device shown in FIG. 7, (a) shows a state when no voltage is applied, and (b) shows a state when the voltage is applied. ing. It is explanatory drawing which shows schematic structure of the structure formed in the electrode surface in the liquid crystal display panel of a MVA structure, (a) is sectional drawing seen from the substrate surface parallel direction, (b) is seen from the substrate surface normal direction. It is a plan view It is explanatory drawing which shows schematic structure of the structure formed in the electrode surface in the liquid crystal display panel of a CSP structure, (a) is sectional drawing seen from the substrate surface parallel direction, (b) is seen from the substrate surface normal direction. It is a plan view The relationship between the gradation of the video signal and the luminance ratio normalized by the luminance when the liquid crystal display panel not performing the divided sub-pixel drive in the liquid crystal display device shown in FIG. 7 is viewed from a plurality of viewing angle directions. It is a graph which shows. The relationship between the gray scale of the video signal and the luminance ratio obtained by normalizing the luminance to be viewed when the liquid crystal display panel performing the divided sub-pixel driving in the liquid crystal display device shown in FIG. 7 is viewed from a plurality of viewing angles. It is a graph which shows. (A)-(g) is explanatory drawing which shows an example of the display nonuniformity visually recognized according to the viewing angle direction in the liquid crystal display device shown in FIG. It is explanatory drawing which shows the calculation performed by the process for producing | generating the correction data in the liquid crystal display device shown in FIG. (A) is explanatory drawing which shows an example of the display screen at the time of displaying the solid image of the gradation V0 in the liquid crystal display device of FIG. 7, (b) is the measurement which measured the brightness | luminance of the display screen of (a). It is the graph which extracted the data for 1 line extended | stretched in the horizontal direction in data, (c) performs the two-dimensional Fourier transformation with respect to the measurement data of (b), removes a high frequency component, and is two-dimensional inverse Fourier It is a graph which shows the data obtained by performing conversion. It is explanatory drawing which shows the structure of the TFT glass substrate with which the liquid crystal display panel of the liquid crystal display device concerning Embodiment 3 of this invention is equipped. FIG. 23 is an explanatory diagram illustrating signals handled by the liquid crystal display device illustrated in FIG. 22, where (a) is an input video signal for each subpixel input to the subpixel dividing unit, and (b) is corrected by the correction calculation unit. The corrected video signal for each divided sub-pixel, (c) shows the output signal from the sub-pixel rearrangement unit to the liquid crystal controller. It is explanatory drawing which shows the structure of the liquid crystal display device concerning Embodiment 4 of this invention. FIG. 26 is an explanatory diagram showing the frequency of gradations used in a divided video signal obtained by dividing a video signal of a subpixel into a video signal of a divided subpixel in the liquid crystal display device shown in FIG. 25. It is explanatory drawing which shows the structure of the liquid crystal display device concerning Embodiment 5 of this invention. It is explanatory drawing which shows the structure of the TFT glass substrate with which the liquid crystal display panel of the liquid crystal display device shown in FIG. 27 is equipped. It is explanatory drawing which shows the structure of the gradation DAC with which the source driver of the liquid crystal display device shown in FIG. 27 is equipped. (A) And (b) is explanatory drawing which shows an example of the setting information of the output voltage stored in two non-volatile memories with which the gradation DAC shown in FIG. 27 is equipped. It is explanatory drawing which shows the structure of the connection part of the source driver and liquid crystal display panel in the liquid crystal display device shown in FIG. It is explanatory drawing which shows the structural example of the source driver of the liquid crystal display device shown in FIG. FIG. 28 is an explanatory diagram illustrating an arithmetic expression used in the liquid crystal display device illustrated in FIG. 27. FIG. 28 is a voltage luminance ratio curve of a liquid crystal showing a luminance ratio with respect to a voltage applied to a divided sub-pixel in the liquid crystal display device shown in FIG. 27. It is explanatory drawing which shows the voltage waveform supplied to a division | segmentation sub pixel in the liquid crystal display device shown in FIG. It is explanatory drawing which shows the polarity of the voltage supplied to a division | segmentation sub pixel in the liquid crystal display device shown in FIG. It is explanatory drawing which shows the waveform of the drive signal of the liquid crystal display panel in the liquid crystal display device shown in FIG. It is a graph which shows the viewing angle characteristic of the liquid crystal display device shown in FIG. FIG. 27A shows an example of setting information according to a comparative example in which the voltage applied to the source bus line is set based on only one type of setting information, and FIG. 27B shows the setting information based on the setting information of FIG. 5 is a graph showing viewing angle characteristics of a comparative example in which the liquid crystal display device shown in FIG. 27 shows setting information of applied voltage to the source bus line used for display for measurement performed when generating correction data of the liquid crystal display device shown in FIG. 27, (a) shows setting information for dark division sub-pixels, (B) shows setting information for the bright division sub-pixel. It is explanatory drawing which shows the structure of the liquid crystal display device concerning Embodiment 6 of this invention. It is explanatory drawing which shows the structure of the TFT glass substrate and CF glass substrate with which the liquid crystal display panel of the liquid crystal display device shown in FIG. 41 is equipped. FIG. 42 is an equivalent circuit diagram of each divided sub-pixel in the liquid crystal display device shown in FIG. 41. 42 is an explanatory diagram showing a configuration of a VCOM power supply circuit provided in the liquid crystal display device shown in FIG. 41. FIG. 42 is an explanatory diagram showing a configuration of a CS power supply circuit provided in the liquid crystal display device shown in FIG. 41. FIG. FIG. 42 is an explanatory diagram illustrating a configuration example of a gradation DAC provided in the liquid crystal display device illustrated in FIG. 41. 41 shows voltage waveforms of divided sub-pixels when a counter voltage is supplied to each auxiliary capacitance line in the liquid crystal display device shown in FIG. FIG. 42 is an explanatory diagram showing drive voltage waveforms of divided sub-pixels in the liquid crystal display device shown in FIG. 41, where (a) shows the drive voltage waveforms of the bright divided sub-pixels and (b) shows the drive voltage waveforms of the dark-divided sub-pixels. In the liquid crystal display device shown in FIG. 41, an explanation is given of the potential difference between the pixel electrode 34 and the counter electrode 35 in the bright and dark divided subpixels when the amplitude of the output waveform of the CS power supply circuit is 0.2V. FIG. 41 (a) is a graph showing a gradation luminance ratio curve of the liquid crystal display device shown in FIG. 41, and (b) is a gradation luminance ratio curve of a comparative example in which the potential of the auxiliary capacitance line is made constant at the counter electrode potential. It is a graph to show.

Embodiment 1
(1-1. Configuration of Liquid Crystal Display Device 1a)
An embodiment of the present invention will be described. In the present embodiment, display unevenness (also referred to as display spots or color spots) refers to luminance or chromaticity (for each pixel) due to differences in characteristics between pixels (pixels) or differences in backlight characteristics. It means a phenomenon in which the measured brightness and chromaticity) vary. Further, the luminance unevenness means a phenomenon in which the luminance (measured luminance) decreases as the distance from the center portion of the display screen approaches the end portion due to the difference in the backlight characteristics.

  FIG. 1 is an explanatory diagram showing a schematic configuration of a liquid crystal display device 1a according to the present embodiment. As shown in this figure, the liquid crystal display device 1a includes a liquid crystal display panel 10, a gate driver (gate driving means, driving section) 11, a source driver (source driving means, driving section) 12, a liquid crystal controller (driving section) 13, A correction calculation unit 14 and a storage unit 15 are provided.

  The storage unit 15 stores in advance correction data for correcting the input video signal so that display unevenness of the liquid crystal display panel 10 is less visible. In the present embodiment, correction data that makes it difficult to visually recognize display unevenness regardless of the viewing angle direction of the liquid crystal display panel 10, that is, not only when the liquid crystal display panel 10 is viewed from the front (display surface normal direction), but also in an oblique direction ( Correction data that makes it difficult to visually recognize display unevenness even when viewed from a direction inclined with respect to the normal direction of the display surface is created in advance and stored in the storage unit 15. A method for generating correction data will be described later.

  The correction calculation unit 14 performs a correction process corresponding to the correction data read from the storage unit 15 on the input video signal, generates a corrected video signal, and transmits the corrected video signal to the liquid crystal controller 13.

  The liquid crystal controller 13 generates various control signals for controlling the operation of the liquid crystal display panel 10 based on the corrected video signal input from the correction calculation unit 14 and outputs the control signals to the gate driver 11 and the source driver 12.

  The gate driver 11 and the source driver 12 drive each divided subpixel of the liquid crystal display panel 10 based on a control signal input from the liquid crystal controller 13.

  As shown in FIG. 1, the liquid crystal display panel 10 includes a large number of pixels 20, and each pixel 20 includes three subpixels 21. That is, the pixel 20 is configured by three subpixels 21 of an R (red) subpixel 21R, a G (green) subpixel 21G, and a B (blue) subpixel 21B. Each sub-pixel 21 includes two divided sub-pixels (divided picture elements) 22. That is, the subpixel 21R includes divided subpixels 22Ra and 22Rb, the subpixel 21G includes divided subpixels 22Ga and 22Gb, and the subpixel 21B includes divided subpixels 22Ba and 22Bb.

  In the present embodiment, as the liquid crystal display panel 10, a panel that employs multi-pixels is used. In order to improve the viewing angle characteristics of the vertical electric field type VA mode, multi-pixel gamma control is applied to pixels of MVA (multi-domain VA) or CSP (circular structure or circular protrusion. CIRCLE SHAPE PROJECTION). It drives with the drive method called.

(1-2. Generation of correction data)
Next, a method for generating correction data will be described.

(1-2-1. Calculation of correction value when viewed from a specific direction)
FIG. 2 is a graph showing gradation luminance ratio characteristics in each divided sub-pixel of the liquid crystal display panel 10. Each curve shown in the graph of FIG. 2 indicates a gradation visually recognized when viewed from different viewing angle directions, and the lowermost curve indicates the case viewed from the front, and is located on the upper side. The curve shows the viewing angle (inclination angle with respect to the normal direction of the display surface of the liquid crystal display panel 10).

  As can be seen from FIG. 2, as the viewing angle of the liquid crystal display panel 10 increases, the luminance ratio increases, particularly at a gray level, and the image is viewed as whitish. For this reason, when a natural image is displayed, the display screen is easily visually recognized as a whitish image when viewed from an oblique direction. As can be seen from FIG. 2, the degree of change depends on which azimuth (the angle with respect to the reference azimuth in the direction of viewing the display screen when the predetermined direction is the reference azimuth (0 °) in a plane parallel to the display screen). Is different. This is a characteristic unique to a liquid crystal display panel.

  Let G (t, φ, θ) be the luminance characteristic for the input video signal. Here, t is the gradation of the input video signal, t = 0 indicates black (the lowest luminance), and the larger the value of t, the higher the luminance. φ and θ represent from which direction the liquid crystal display panel 10 is viewed in polar coordinates, and φ is an orientation in a direction parallel to the display surface of the liquid crystal display panel 10 (a predetermined value in a plane parallel to the display surface of the liquid crystal display panel 10). Rotation angle with respect to the predetermined direction when the direction is 0), and θ represents an angle formed with the normal direction of the display surface of the liquid crystal display panel 10. In the following description, a description will be given using a luminance ratio normalized.

Since the luminance is maximum when t is the maximum value tmax, the luminance ratio Gnorm (t, φ, θ) is
Gnorm (t, φ, θ) = G (t, φ, θ) / G (tmax, φ, θ)
It is represented by

  The above formula is for a monochrome panel, but in the case of a color panel, the same processing may be performed based on the above formula for each color to be configured. For example, in the case of a three-color panel, there are usually parameters of red, green and blue, which are the three primary colors, and in the case of a four-color panel, there are parameters such as yellow in addition to red, green and blue. May be performed.

In general, γ = 2.2 is used as the standard for the front-side gradation luminance ratio characteristic.
Gnorm (t, 0,0) = Gnorm (0,0,0) + 1 / (Gnorm (tmax, 0,0) −Gnorm (0,0,0)) × (t / tmax) ^2.2
The design is carried out with the curve indicated by.

When the gradation of the input video signal at coordinates (x, y) in the liquid crystal display panel 10 is t (x, y), the luminance ratio Lnorm is
Lnorm (x, y, φ, θ) = Gnorm (t (x, y), φ, θ)
It becomes.

As shown in FIG. 1, when one subpixel 21 is divided into two divided subpixels 22a and 22b, the luminance ratio LHnorm of the bright side divided subpixel (bright divided subpixel) and the dark side divided subpixel. The average value of the luminance ratio LLnorm of (dark division subpixel) and the luminance ratio Lnorm of the subpixel 21 before division are:
Lnorm (x, y, φ, θ) = (LHnorm (x, y, φ, θ) + LLnorm (x, y, φ, θ)) / 2
And become equal. Note that the bright division subpixel and the dark division subpixel in the subpixel are periodically replaced.

  Since the viewing angle characteristics of the divided subpixels change depending on the luminance, the viewing angle characteristics change by changing the combination of the luminance of the bright divided subpixel and the luminance of the dark divided subpixel. Therefore, the viewing angle can be improved by optimizing this combination.

Further, when LHnorm and LLnorm are rewritten to functions GHnorm and GLnorm of the gradation luminance ratio,
LHnorm (x, y, φ, θ) = GHnorm (t (x, y), φ, θ)
LLnorm (x, y, φ, θ) = GLnorm (t (x, y), φ, θ)
It becomes. Since GHnorm and GLnorm do not depend on x and y like Gnorm, the same processing may be performed for each pixel.

  FIG. 3 shows the display screen slanted when the subpixel is divided into two divided subpixels as shown in FIG. 1 and the combination of gradations of the divided subpixels with respect to the gradation of the input video signal is optimized. An example of the gradation luminance ratio curve (gradation luminance ratio curve) when viewed from the direction is shown. As shown in this figure, by optimizing the combination of gradations of each divided sub-pixel, the gradation luminance ratio curve when viewed from the diagonal can be made closer to the gradation luminance ratio curve when viewed from the front. it can.

  Note that the gradation luminance ratio curve when viewed from the diagonal and the gradation luminance ratio curve when viewed from the front are not the same because the values that can be selected as the gradation values of each sub-pixel are viewed obliquely. This is because it is necessary to select from the values of the gradation luminance value curve of each divided sub-pixel. Note that the method of optimizing the gradation of each divided subpixel differs depending on the driving method of the divided subpixels. Specific examples of the method for optimizing the gradation of each divided subpixel and the method for driving the divided subpixel will be described in the second and later embodiments.

  FIG. 4 shows an example of a display screen on which a gray solid image of V127 (pixel value (gradation value) 127 when the image data is 8 bits) is displayed. As shown in this figure, the display screen of the liquid crystal display device may have uneven display unevenness such as a darkly displayed part or a brightly displayed part due to manufacturing variations of the liquid crystal display panel.

  FIG. 5A shows the luminance data of one line in the x direction among the results of measuring the display luminance value of the display screen shown in FIG. 4 from a specific direction. The method for measuring the luminance value is not particularly limited. For example, the surface of the luminance chromaticity measuring device (UA-1000A, etc.) manufactured by Topcon, the two-dimensional color luminance meter (CA-2000, etc.) manufactured by Konica Minolta. A luminance meter may be used, and a high-definition digital camera such as Nikon Corporation or Sony Corporation, or an industrial camera may be used.

  FIG. 5B is obtained by applying a low pass filter to the measurement result of FIG. By passing through a low-pass filter, high frequency components are eliminated and the entire screen changes gently. Since gentle changes are not easily recognized by the human eye, it is possible to correct the spots. A low-pass filter is used because a backlight (not shown) provided in a liquid crystal display device often has a bright center in the display screen and a dark peripheral edge. This is because the brightness at the center becomes too dark.

  In the present embodiment, the difference between the luminance value in FIG. 5A and the luminance value in FIG. 5B is calculated as a correction value. Thereby, by adding a correction value to the input video signal, it is possible to obtain the same data as after passing through the low-pass filter.

  Note that the display unevenness that occurs in the liquid crystal display panel may have gradation dependency, for example, a patchy display unevenness caused by variations in cell thickness. For this reason, in this embodiment, for a plurality of input gradations (specifically, V31, V63, V95, V127, V159, V191, V223), the difference between the measurement result of the luminance value and the result of applying the low-pass filter thereto. Is used to calculate the correction value, and other gradation correction values are calculated by interpolation. As a result, different corrections can be performed for each gradation, so that even display unevenness having gradation dependency can be corrected appropriately.

(1-2-2. Calculation of correction data)
By the way, in the case of the multi-pixel described above, the viewing angle characteristic is improved by adjusting the combination of the luminance values of the divided sub-pixels. Therefore, the luminance of the sub-pixels in the input video signal and each divided sub-pixel constituting the sub-pixels The brightness is different. For this reason, when correcting display unevenness that depends on gradation, a correction value for display unevenness is generated for the subpixel, whereas the voltage actually applied to the liquid crystal is different for each divided subpixel. become.

  As a result, when the input video signal is corrected using the correction value calculated based on the result measured from the specific direction, the total luminance value of the divided sub-pixels is corrected when viewed from the specific direction. Therefore, the correction including the difference caused by dividing the sub-pixel into the divided sub-pixels can be performed. For this reason, it seems as if correction of display unevenness when viewed from the direction of measurement is performed appropriately.

  However, in reality, the display unevenness correction in the divided sub-pixels is not appropriately performed. For example, when only one of the bright divided sub-pixels and the dark divided sub-pixels is lit, even when viewed from a specific direction. Display unevenness is visually recognized.

  In the divided subpixel driving, the ratio of the luminance of the bright divided subpixel and the luminance of the dark divided subpixel to the visually recognized luminance varies depending on the viewing angle. For this reason, when viewed from the direction of measurement for calculating the correction value, the display unevenness that was not seen by canceling out the bright division sub-pixel and the dark division sub-pixel is the same as the direction of measurement. When viewed from different directions, they are not canceled out and display unevenness is visually recognized.

  This point will be specifically described as follows. First, the luminance ratio before correction is Lnorm_r (x, y, φ, θ). For example, Lnorm_r (222, 320, 0, 0) represents a luminance ratio obtained by measuring the coordinates (222, 320) from the front (display screen normal direction). Further, the corrected luminance ratio, that is, the luminance ratio after passing through the low-pass filter is defined as Lnorm '.

In this case, the luminance ratio Lnorm_r (x, y, 0, 0, t) before correction (measurement result) and the corrected luminance ratio Lnorm ′ (x, y, 0, 0, t) when measured from the front side The relationship
Lnorm ′ (x, y, 0, 0, t) = Lnorm_r (x, y, 0, 0, t) + Lmura (x, y, t) (1)
It is represented by Here, Lmura is a display unevenness correction value, and t is the gradation of the input video signal.

The above plaque correction value is
Lmura (x, y, t) = Lnorm ′ (x, y, 0, 0, t) −Lnorm_r (x, y, 0, 0, t) (2)
More demanded.

Lnorm ′ (x, y, 0, 0, t) is
L ′ (x, y, c, t) = L (x, y, c, t + t_mura) (3)
Can be rewritten. Here, c represents a sub-pixel color, and t_mura represents a gradation correction value.

  In the case of multi-pixels, since one subpixel is divided into two divided subpixels, L (x, y, c, t) is expressed by the following equation.

Here, m represents the number of divided subpixels, and M represents the number of divided subpixels (the number of divided subpixels for one subpixel).

Therefore, when dividing one subpixel into two divided subpixels,
L (x, y, c, t) = Lsub (x, y, c, t, 0) + Lsub (x, y, c, t, 1) (5)
And the correction value is
L (x, y, c, t + t_mura) = Lsub (x, y, c, t + t_mura, 0) + Lsub (x, y, c, t + t_mura, 1) (6)
It becomes.

  The correction value calculated in this way is the same as the above equation (3) because it satisfies the above equation (4) when viewed from the front.

  However, when viewed from an oblique direction, the gradation luminance ratio curve is different from that viewed from the front, and therefore the above equation (6) does not hold. Therefore, even if the input video signal is corrected based on the correction value, display unevenness is visually recognized when viewed from an oblique direction.

  Therefore, in the present embodiment, the brightness of each part of the liquid crystal display panel on which the solid image (measurement image) is displayed is calculated from a plurality of directions, and correction values corresponding to the respective measurement directions are calculated. Based on this, correction data to be applied to the input video signal is calculated. That is, the correction value is calculated so that the difference between the left side and the right side in Equation (6) is small even when viewed from an oblique direction.

  First, the brightness of each part of the liquid crystal display panel on which the solid image (measurement image) is displayed is set to the clockwise direction φ with respect to the reference direction in the plane parallel to the display screen and the tilt angle (viewing angle) θ with respect to the normal direction of the display screen Measure from multiple directions with different combinations.

  Specifically, in this embodiment, the combinations (φ, θ) of the azimuth φ and the viewing angle θ are (0, 0), (0, 0.25π), (0.25π, 0.25π), ( 0.5π, 0.25π), (0.75π, 0.25π), (π, 0.25π), (1.25π, 0.25π), (1.5π, 0.25π), (1. Measurement is performed from nine directions (75π, 0.25π). The values of φ and θ are shown in radians.

  FIG. 6 is an explanatory diagram showing an example of a measurement method when measuring luminance values when viewed from a plurality of directions. As shown in this figure, the liquid crystal display panel 10 is placed on the variable spacers 2 and 2 and is variable so that the display surface of the liquid crystal display panel 10 is horizontal while looking at the horizontal column 3 attached to the liquid crystal display panel 10. Adjust the height of spacers 2 and 2.

  A measuring device 5 is attached to a robot arm 4 that can move in the horizontal direction (x direction and y direction) and the vertical direction (z direction). The measuring device 5 is attached to the robot arm 4 so as to be rotatable in the α direction parallel to the vertical direction and the β direction parallel to the horizontal direction. The positional relationship between the liquid crystal display panel 10 placed on the variable spacers 2 and 2 and the measuring device 5 is calibrated in advance.

  Then, the robot arm 4 and the measurement device 5 are moved to measure the luminance of each part of the liquid crystal display panel 10 from a desired measurement direction.

  As the measuring device 5, for example, a luminance and chromaticity measuring device (UA-1000A, etc.) manufactured by Topcon Corporation, a surface luminance meter such as a two-dimensional color luminance meter (CA-2000, etc.) manufactured by Konica Minolta, or Nikon Corporation A high-definition digital camera such as Sony Corporation or an industrial camera can be used.

Then, correction data (second correction data) to be applied to the input video signal is obtained by adding a predetermined weight to the correction value (first correction data) calculated in each direction based on the measurement result in each direction. ) Is calculated. The weighting method may be set as appropriate depending on how much the oblique viewing angle is accepted, and is not particularly limited. For example, if the emphasis is placed on the front and the oblique viewing is considered, What is necessary is just to set like Formula (7).
Lmura (x, y, c, t) =
1 / 1.48 × (Ls_mura (x, y, c, t, 0, 0)
+ 0.06 × Ls_mura (x, y, c, t, 0, 0.25π)
+ 0.06 × Ls_mura (x, y, c, t, 0.25π, 0.25π)
+ 0.06 × Ls_mura (x, y, c, t, 0.5π, 0.25π)
+ 0.06 × Ls_mura (x, y, c, t, 0.75π, 0.25π)
+ 0.06 × Ls_mura (x, y, c, t, π, 0.25π)
+ 0.06 × Ls_mura (x, y, c, t, 1.25π, 0.25π)
+ 0.06 × Ls_mura (x, y, c, t, 1.5π, 0.25π)
+ 0.06 × Ls_mura (x, y, c, t, 1.75π, 0.25π))
... (7)
Ls_mura is expressed by the following formula.

  Further, (i) the second correction data may be stored in the storage unit 15, and the correction calculation unit 14 may read out the second correction data from the storage unit 15 to perform correction, and (ii) the storage unit. A plurality of the first correction data is stored in 15, the correction calculation unit 14 reads out each first correction data from the storage unit 15, and generates the second correction data by combining them, and the generated second correction data You may make it correct | amend based on data.

  The above processing is performed for each color component (each subpixel) for each pixel, and correction data for each subpixel is generated. In the case of luminance unevenness correction, correction data may be generated for each luminance component of all pixels.

  The storage unit 15 stores correction data calculated in this way.

(1-3. Correction of input video signal)
The correction calculation unit 14 corrects the input video signal based on the correction data stored in the storage unit 15 and generates a corrected video signal.

Specifically, if the gradation luminance characteristic when viewed from the front of the liquid crystal display panel 10 is ganma, the luminance L (t (x, y, c)) is
L (t (x, y, c)) = ganma (t (x, y, c)) (8)
It is represented by

The corrected luminance L ′ (t (x, y, c)) is
L ′ (t (x, y, c)) = L (t (x, y, c)) + L_mura (x, y, c, t (x, y, c)) (9)
It is represented by

The corrected video signal is t ′ (x, y, c) = ganma ⁻¹ (L ′ (t (x, y, c))) (10)
It is represented by

  Therefore, the liquid crystal controller 13 controls each divided subpixel of the liquid crystal display panel 10 based on the corrected video signal t ′ (x, y, c).

  Thereby, even when the liquid crystal display panel 10 is viewed from an oblique direction, display unevenness can be corrected appropriately. That is, in the conventional technology, when the display screen is viewed from an oblique direction, display unevenness is visually recognized due to the difference in viewing angle characteristics between the bright divided subpixels and the dark divided subpixels. Display unevenness can be suppressed.

[Embodiment 2]
Another embodiment of the present invention will be described. For convenience of explanation, members having the same functions as those in the first embodiment are denoted by the same reference numerals, and description thereof is omitted.

(2-1. Configuration of the liquid crystal display device 1b)
FIG. 7 is an explanatory diagram showing a schematic configuration of the liquid crystal display device 1b according to the present embodiment. As shown in this figure, in addition to the configuration of the liquid crystal display device 1a according to the first embodiment, the liquid crystal display device 1b includes a sub-pixel division unit (picture element division unit) 16, a division LUT (division setting storage unit) 17, A pseudo gradation generation unit 18 and a subpixel rearrangement unit 19 are provided.

  The subpixel division unit 16 uses the conversion LUT (lookup table, division setting information) stored in the division LUT 17 to correspond the input video signal to each of the division subpixels provided in the liquid crystal display panel 10. Is converted (divided) into divided video signals that are video signals to be processed. That is, the subpixel dividing unit 16 divides the data of each subpixel in the input video signal into data corresponding to the divided subpixels. In the configuration shown in FIG. 7, conversion to a video signal in units of divided subpixels is performed using the LUT stored in the divided LUT 17. However, the present invention is not limited to this, and an arithmetic expression for conversion (division setting information) May be stored, and conversion may be performed by calculation.

  The storage unit 15 stores correction data for correcting display unevenness of the liquid crystal display panel 10 in advance. Since the correction data differs depending on the individual liquid crystal display panel, the correction data is obtained based on display unevenness information (information indicating the result of measuring the display screen displaying the measurement image from a plurality of viewing angles) for each liquid crystal display panel. Generate and write from the outside. The correction data is generated for each subpixel and for each gradation.

  The correction calculator 14 corrects the divided sub-pixel video signal so that the display unevenness of the liquid crystal display panel 10 is less visible. Specifically, the correction calculation unit 14 reads correction data corresponding to the gradation value (or luminance value) of the correction target subpixel in the video signal from the storage unit 15, and each subpixel based on the read correction data. To correct the tone.

  The pseudo gradation generation unit 18 performs a pseudo gradation generation process for expressing the display image with a greater number of gradations than the number of gradations of the video signal. For example, the pseudo gradation generation unit 18 corrects the video signal so as to perform the pseudo gradation expression using a pseudo gradation technique such as FRC (frame rate control).

  The subpixel rearrangement unit 19 rearranges the data of each divided subpixel according to the wiring of the liquid crystal display panel 10.

  The liquid crystal controller 13 generates a control signal for operating the gate driver 11 and the source driver 12 of the liquid crystal display panel 10 based on the video signal input from the subpixel rearrangement unit 19, and the gate driver 11 and the source driver are generated. 12 is output.

  The gate driver 11 and the source driver 12 drive each subpixel of the liquid crystal display panel 10 based on a control signal input from the liquid crystal controller 13.

  FIG. 8 is a cross-sectional view of the liquid crystal display panel 10. As shown in this figure, the liquid crystal display panel 10 includes a TFT glass substrate 31, a CF glass substrate 32, a liquid crystal layer 33, a pixel electrode 34, a counter electrode (common electrode) 35, a color filter (CF) 36, a TFT side polarizing plate. 37, a CF side polarizing plate 38, and an optical sheet group 39.

  Specifically, the TFT glass substrate 31 and the CF glass substrate 32 are arranged to face each other with a predetermined interval, and a liquid crystal material 33 is sealed between the two glass substrates to form a liquid crystal layer 33.

  FIG. 9 is an explanatory diagram showing a schematic configuration of the TFT glass substrate 31, and FIG. 10 is an equivalent circuit diagram of each divided sub-pixel.

  As shown in FIG. 9, on the surface of the TFT glass substrate 31 on the liquid crystal layer 33 side, a large number of gate bus lines g and a large number of source bus lines s are formed so as to cross each other in a grid pattern. A TFT (Thin Film Transistor) 51 and a pixel electrode 34 are formed at each intersection of the gate bus line g and the source bus line s.

  Each gate bus line g is connected to the gate driver 11, and each source bus line s is connected to the source driver 12.

  The gate bus lines g are arranged so as to extend in the horizontal direction of the display screen (longitudinal direction of the rectangular display screen), and the number of the gate bus lines g is arranged in the vertical direction (short direction of the rectangular display screen). The number of pixels is double (for example, in the case of FHD in which the number of display pixels in the vertical direction is 1080, the number of gate bus lines g is 1080 × 2 = 2160).

  The source bus lines s are wired so as to extend in the vertical direction of the liquid crystal display panel 10, and the number thereof is three times the number of display pixels arranged in the horizontal direction (for example, the number of display pixels arranged in the horizontal direction is 1920). In the case of FHD, the number of source bus lines s is 1920 × 3 = 5760).

  As shown in FIG. 10, the gate terminal 51 g of the TFT 51 is connected to the gate bus line g, the source terminal 51 s is connected to the source bus line s, and the drain terminal 51 d is connected to the pixel electrode 34. The pixel electrode 34 and the TFT 51 are provided for each divided subpixel.

  The TFT 51 is used as a switching element for each divided sub-pixel. When the potential of the gate terminal 51g of the TFT 51 becomes higher than the potential of the source terminal 51s, the TFT 51 is turned on, and the potential of the source bus line s is applied to the pixel electrode 34 connected to the drain terminal 51d.

  As shown in FIGS. 9 and 10, the counter electrode 35, the counter electrode wiring 52, and the auxiliary capacitance wiring (auxiliary capacitance electrode) CS are formed on the surface of the CF glass substrate 32 on the liquid crystal layer 33 side. Yes. The counter electrode 35 is formed on substantially the entire display area of the CF glass substrate 32. The storage capacitor line CS is wired so as to form a storage capacitor (CS) by capacitively connecting to the pixel electrode 34.

  Also, as shown in FIG. 8, a TFT side polarizing plate 37 is disposed on the surface of the TFT glass substrate 31 opposite to the liquid crystal layer 33, and the CF glass substrate 32 is opposite to the liquid crystal layer 33. An RGB color filter 36 and a CF side polarizing plate 38 are arranged on the surface. The TFT side polarizing plate 37 and the CF side polarizing plate 38 each pass light having a specific polarization axis.

  As the color filter 36, a color filter of any color of RGB (a color filter that passes only light in a wavelength region corresponding to any of RGB) for each divided sub-pixel (at a position corresponding to each pixel electrode 34). Is formed.

  Further, an optical sheet group 39 composed of a plurality of optical function sheets such as a diffusion sheet and a lens sheet is disposed at a position facing the back surface side of the TFT glass substrate 31, and further on the back surface side of the optical sheet group 39. Is provided with a backlight 40.

  The backlight 40 includes a plurality of LEDs 41 and a reflector 42 that reflects the light emitted from each LED 41 to the liquid crystal display panel 10 side. The light source of the backlight 40 is not limited to the LED, and other light sources such as a cold cathode tube may be used.

  Thereby, the light emitted from the backlight 40 is diffused and condensed by the optical sheet group 39 and enters the TFT side polarizing plate 37. The TFT side polarizing plate 37 allows only light having a specific polarization axis to pass therethrough, and the light passing through the TFT side polarizing plate 37 passes through the TFT glass substrate 31 and enters the liquid crystal layer 33.

  A potential corresponding to the video signal is applied to the pixel electrode of each divided sub-pixel formed on the TFT glass substrate 31, and a predetermined common potential (a predetermined potential) is applied to the counter electrode 35 and the auxiliary capacitance wiring CS formed on the CF glass substrate 32. VCOM voltage) is applied.

  FIG. 11 is an explanatory diagram showing a waveform of a voltage applied to each divided sub-pixel. As shown in this figure, when the potential of the gate bus line g (gate bus line potential) is switched from low level to high level, the TFT 51 connected to the gate bus line g is turned on (conductive state), and the source The potential of the bus line s (source bus line potential) is applied to the pixel electrode 34 via the TFT 51. As a result, charges are charged in the liquid crystal capacitor CL (see FIG. 10) formed between the pixel electrode 34 and the counter electrode 35 and the auxiliary capacitor C formed between the pixel electrode 34 and the auxiliary capacitor line CS. The The charge of the auxiliary capacitor C is held at a potential just before the TFT 51 is turned off even after the potential of the gate bus line g becomes low level and the TFT 51 is turned off (shut off state). The liquid crystal molecules move (or rotate) by the electric field generated by the charges charged in the liquid crystal capacitor CL and the auxiliary capacitor C, and the liquid crystal display panel 10 displays.

  In other words, the liquid crystal sealed in the liquid crystal layer 33 changes the orientation direction of the liquid crystal molecules due to the potential difference between the pixel electrode 34 and the counter electrode 35, thereby changing the polarization axis (polarization amount) of the light passing through the liquid crystal layer 33. To do. Therefore, by changing the potential difference between the pixel electrode 34 and the counter electrode 35 according to the video signal, the amount of polarization of light passing through the liquid crystal layer 33 is changed, and the amount of light passing through the CF side polarizing plate 38 is changed. Can be changed. Thereby, it is possible to display according to the video signal by controlling the display gradation of each divided sub-pixel.

  FIG. 12 is an explanatory diagram showing output signals of the gate driver 11 and the source driver 12. In the figure, S0, S1, S2,... S5759 indicate the numbers of the source bus lines s, and G0, G1, G2,... G1079 indicate the numbers of the gate bus lines g.

  As shown in FIG. 12, the gate driver 11 sequentially switches each gate bus line g from the G0 to the G1079 to the high level. As a result, the gate bus lines g are set to the high level one by one, and the divided sub-pixels connected to the gate bus lines g that are set to the high level are supplied from the source driver 12 via the source bus lines s (S0 to S5759). A voltage corresponding to the display gradation is applied. As described above, in this embodiment, display is performed by line order driving in which writing is sequentially performed one by one for each gate bus line.

  FIG. 13 is an explanatory diagram showing input / output signals of the source driver 12. SSP is a source start pulse, which is a control signal representing the start position of data for one gate bus line. R (x, y), G (x, y), and B (x, y) are signals representing the gradation data of red, green, and blue for the pixel at coordinates (x, y), respectively.

  As shown in FIG. 13, after the start pulse SSP is input, the data of the gate bus line y is sequentially input. The source driver 12 stores the input grayscale data, and stores the potential of each source bus line s at a timing synchronized with the rise of the latch signal LS after the input of the grayscale data for one gate bus line is completed. The potentials are switched simultaneously according to the gradation of the gate bus line y.

  FIG. 14A shows the input video signals r (x, y), g (x, y), and b (x, y) for each sub-pixel input to the sub-pixel dividing unit 16. ) Is a corrected video signal RH (x, y), RL (x, y), GH (x, y), GL (x, y), BH (x, y) for each divided sub-pixel corrected by the correction calculation unit 14. y), BL (x, y), and (c) shows output signals RH (x, y), RL (x, y), GH (x, y) from the sub-pixel rearrangement unit 19 to the liquid crystal controller 13. y), GL (x, y), BH (x, y), and BL (x, y) are shown.

  As shown in FIG. 14C, in this embodiment, the subpixel rearrangement unit 19 applies each bright divided subpixel connected to the gate bus line g when a gate bus line g is selected. When a potential corresponding to the video signal is applied and the next gate bus line g is selected, a potential corresponding to the video signal is applied to each dark division sub-pixel connected to the gate bus line g. The data of each divided subpixel is rearranged and output to the liquid crystal controller 13.

(2-2. Divided subpixel drive)
Next, the operation of the liquid crystal display device 1b will be described. Here, for convenience of explanation, a case where the input video signal is a single color will be described. When the liquid crystal display panel 10 performs multi-color display, the same processing as that for a single color may be performed for each color. For example, if there are red, green and blue sub-pixels, the same processing may be performed for the three colors red, green and blue. The same processing may be performed for the four colors.

  Let the gradation of the input video signal be t (x, y). Here, the variable x represents the x coordinate of the input screen, and the variable y represents the y coordinate of the input screen. The gradation t takes a value from 0 to 255 in the case of an 8-bit input video signal and 0 to 1023 in the case of 10 bits. For example, if t (0,0) = 255, it means that the gradation of the coordinate (0,0) is 255.

  In this embodiment, an example of 8 bits will be described. In the present embodiment, an example in which the resolution of the liquid crystal display device 1b is FHD (1920 × 1080 pixels) will be described. Therefore, since the number of display pixels of the liquid crystal display device 1b is 1920 × 1080, x is a value from 0 to 1919 and y is a value from 0 to 1079.

  In the VA mode liquid crystal display device, when no voltage is applied, the liquid crystal molecules are perpendicular to the direction parallel to the substrate surface of the liquid crystal display panel 10 as shown in FIG.

  On the other hand, when a voltage is applied between the pixel electrode 34 and the counter electrode 35 to apply a voltage in the normal direction of the substrate surface, as shown in FIG. Tilt. Due to the inclination of the liquid crystal molecules, the amount of rotation of the polarization axis of the light passing through the liquid crystal layer 33 changes. For this reason, if the polarizing axes of the TFT side polarizing plate (back polarizing plate) 37 and the CF side polarizing plate (front polarizing plate) 38 are crossed at right angles, light is applied when no voltage is applied to the liquid crystal layer 33. Instead, the light is allowed to pass by the amount of rotation of the polarization axis when a voltage is applied. Thus, in the liquid crystal display device 1b, gradation display is performed by utilizing the change in the amount of light passing through the liquid crystal display panel 10 in accordance with the applied voltage.

  However, in the VA mode liquid crystal display device, since the liquid crystal molecules themselves are elongated molecules, and the polarization axis is rotated by birefringing light within the molecules, the liquid crystal display panel 10 The display characteristics change depending on the relationship with the viewing direction (viewing angle direction).

  In order to suppress such a change in display characteristics depending on the viewing angle direction, there is a technique for controlling the tilting direction of liquid crystal molecules by arranging a structure on the surface of an electrode. This is called MVA (multi-domain VA) or CSP (circular structure).

  16A and 16B are explanatory views showing a schematic configuration of a structure 61 formed on the electrode surface in MVA. FIG. 16A is a cross-sectional view seen from the substrate surface parallel direction, and FIG. 16B is a view seen from the substrate surface normal direction. It is a top view. FIGS. 17A and 17B are explanatory views showing a schematic configuration of the structure 62 formed on the electrode surface in the CSP. FIG. 17A is a cross-sectional view seen from the substrate surface parallel direction, and FIG. 17B is the substrate surface normal direction. It is the top view seen from.

  As shown in FIGS. 16 and 17, the structures 61 and 62 formed on the electrode surface distribute the directions in which the liquid crystal molecules are tilted into a plurality of directions. As described above, the direction in which the liquid crystal molecules are tilted is distributed in a plurality of directions, so that a part of the change in the viewing angle characteristics caused by the tilting of the liquid crystal molecules is offset. For example, in the example shown in FIGS. 16 and 17, the number of liquid crystal molecules tilted to the left side is equal to the number of liquid crystal molecules tilted to the right side, and the change in viewing angle characteristics due to the tilt of each liquid crystal molecule is canceled out.

  Note that the shape of the structure formed on the electrode surface is different between MVA and CSP. Specifically, in MVA, as shown in FIG. 16B, a quadrangular pyramid structure 61 is formed, and the directions in which the liquid crystal molecules are tilted are distributed in four directions. On the other hand, in the CSP, as shown in FIG. 17B, a conical structure 62 is formed, and the direction in which the liquid crystal molecules incline changes continuously. Since the structure 61 used in the MVA has corners and sides, the appearance changes depending on which direction the liquid crystal display panel 10 is viewed. On the other hand, since the CSP is circular when viewed from the normal direction of the substrate surface, no difference occurs when viewed from any direction. In the present embodiment, for the sake of convenience of explanation, the case of the CSP mode that can be described by omitting the direction (the term of φ in the first embodiment) will be described. In the case of the MVA mode, it can be easily expanded by taking the direction into consideration.

  As described above, in the VA mode, by adopting MVA or CSP, it is possible to reduce a difference between when viewed from the front and when viewed from the oblique direction. However, even if MVA or CSP is adopted, the difference between the case of viewing from the front and the case of viewing from the oblique side cannot be completely eliminated, and the appearance differs depending on the viewing angle.

  FIG. 18 shows a video signal level when the liquid crystal display panel 10 is viewed from a plurality of viewing angles when the divided sub-pixel driving is not performed (when the same voltage is applied to the divided sub-pixels constituting the same sub-pixel). It is a graph which shows the relationship between a brightness | luminance and the luminance ratio which normalized the brightness | luminance visually recognized. The x axis indicates the gradation of the video signal, and the y axis indicates the luminance ratio. Each curve in the graph represents a video signal when the tilt angle (in radians) of the viewing angle direction with respect to the substrate surface normal direction when the orientation of the liquid crystal display panel 10 in the substrate surface normal direction is 0 is changed. The relationship between the gradation and the visually recognized luminance ratio is shown. As can be read from the graph of FIG. 18, an error in luminance that is visually recognized increases as the angle formed with the normal direction of the substrate surface increases. Note that the luminance ratio curve when viewed from a direction inclined with respect to the normal direction of the substrate surface is above the graph (the luminance ratio becomes larger) than when viewed from the front (substrate surface normal direction; θ = 0). The display in such a case is visually recognized as a whitish image as compared with the case of viewing from the front.

When the gradation data of the coordinates (x, y) of the input video signal is t (x, y) and the angle of the viewing angle direction with respect to the normal direction of the substrate surface of the liquid crystal display panel 10 is θ, the luminance ratio Lnorm is
Lnorm (x, y, θ) = Gnorm (t (x, y), θ)
It is represented by

  As described above, in this embodiment, one subpixel is divided into two divided subpixels, that is, a bright divided subpixel and a dark divided subpixel.

When the areas of the dark division subpixel and the light division subpixel are equal, the luminance ratio is an average value of the luminance ratio LLnorm of the dark division subpixel and the luminance ratio of the bright division subpixel LHnorm, that is,
Lnorm (x, y, θ) = (LLnorm (x, y, θ) + LHnorm (x, y, θ)) / 2
It becomes.

When this is rewritten in the gradation luminance ratio,
Gnorm (t, θ) = (GLnorm (t, θ) + GHnorm (t, θ)) / 2
It becomes. Gnorm represents the gradation luminance ratio of the sub-pixel, GLnorm represents the gradation luminance ratio of the dark division subpixel, and GHnorm represents the gradation luminance ratio of the bright division subpixel.

Also, the liquid crystal characteristics of the sub-pixels and the liquid crystal characteristics of the individual divided sub-pixels are the same,
Gnorm (t, θ) = (Gnorm (tL (t), θ) + Gnorm (tH (t), θ)) / 2
It is expressed. Here, tL (t) means that the gradation tL (t) of the dark division sub-pixel is output when the input gradation is t. Similarly, tH (t) means that the gradation tH (t) of the bright division subpixel is output when the input gradation is t.

  Viewing angle characteristics can be improved by optimally setting these functions tL and tH.

  Here, the error of the gradation luminance ratio between the case of viewing from the substrate surface normal direction and the case of viewing from the angle inclined by the angle θ with respect to the substrate surface normal direction is defined as follows.

  FIG. 19 shows a case where the liquid crystal display panel 10 is viewed from a plurality of viewing angles when the divided subpixel drive is performed based on the error of the gradation luminance ratio (when the luminance ratio of the divided subpixel is optimized). 4 is a graph showing a relationship between a gradation of a video signal and a luminance ratio obtained by normalizing visually recognized luminance. Each curve in the graph indicates an error when the angle of the viewing angle direction is different from the normal direction of the substrate surface.

  As is apparent from a comparison between FIG. 18 and FIG. 19, by performing divided subpixel driving, when viewed from the substrate surface normal direction and when viewed from the substrate surface normal direction, compared to the case where divided subpixel driving is not performed. On the other hand, it is possible to reduce the deviation of the gradation luminance ratio curve from the case of viewing from a tilted direction. Thereby, viewing angle characteristics can be improved regardless of the viewing angle direction. Note that the bright and dark divided sub-pixels are replaced for each frame (when attention is paid to one divided sub-pixel, the light and dark are switched for each frame).

  By the way, the display unevenness of the liquid crystal display panel may depend on the gradation as described in the first embodiment. For this reason, as shown in FIGS. 20A to 20G, the appearance of display unevenness differs depending on the gradation. Therefore, in order to appropriately correct the display unevenness, it is necessary to prepare correction data for each gradation. Note that if correction data for all gradations (for example, 256 gradations) is stored, the data size of the conversion table increases, so that representative gradation correction data is generated and stored, and other levels are stored. The tone correction data may be generated by interpolation (for example, linear interpolation) using the stored representative gradation correction data.

(1-3. Generation method of correction data)
Next, an example of a method for creating display unevenness correction data in the present embodiment will be described.

First, at the time of generating correction data, the division LUT 17 used by the sub-pixel division unit 16 is set as in the following equation, and all the correction data in the storage unit 15 is set to 0 so that the input and output are the same.
tH (t) = t
tL (t) = t
Note that the gradation luminance ratio is set to satisfy γ = 2.2. For example, when the input signal to the correction calculation unit 14 is 8 bits,
Gnorm (t) = (t / 255) ^2.2
Set to satisfy.

Then, solid data from V0 to V255 (measurement data with the same gradation of all subpixels) is input to the liquid crystal display device 1a, and the luminance of each subpixel is measured at each gradation. The measurement value at this time (measurement value at the input gradation t of coordinates (x, y)) is
Lmeasure (x, y, t)
It is represented by

  In the case of the input gradation V0 (V0 solid data), t = 0 at all coordinates (x, y). Similarly, t = 1 for the input gradation V1, and t = 255 for the input gradation V255.

  Next, the measured luminance data in the case of the input gradation V0 is substituted into the following two-dimensional Fourier transform.

Note that f (x, y) = Lmeasure (x, y, 0), and in the case of a liquid crystal display device with a resolution FHD (1920 × 1080), M = 1920 and N = 2160. With respect to the value of N, the number of display pixels in the vertical direction is multiplied by the number of divisions 2 in order to perform processing with divided sub-pixels (number of divisions of 2).

  By the above two-dimensional Fourier transform, u is converted to a frequency component of x, and v is converted to a frequency component of y. At this time, 0 and u of the u and v are DC components, and the larger the value, the higher the frequency component.

  Display spots (display unevenness) are high-frequency components because they are local changes. In the present embodiment, since it is desired to remove the influence of the display spots (display unevenness), that portion is set to zero. For example, when a change shorter than 1/32 of the length of the liquid crystal display panel 10 is a display spot (display unevenness), the values of F (u, v) where u ≧ 1860 and v ≧ 2092.5 are replaced with 0. Thus, the high frequency component is removed.

  FIG. 21 shows the processing up to this point in a matrix.

  The following two-dimensional inverse Fourier transform is performed on the value from which the high frequency component has been removed as described above.

The result obtained by this two-dimensional inverse Fourier transform is
Llp (x, y, 0) = f (x, y)
And

  FIG. 22A is an explanatory diagram showing an example of a display screen when a solid image of gradation V0 is displayed, and FIG. 22B is a horizontal direction in the measurement data obtained by measuring the luminance of the display screen of FIG. It is the graph which extracted the data for 1 line extended | stretched in (x direction), (c) performs two-dimensional Fourier transformation with respect to the measurement data of (b), removes a high frequency component, and is two-dimensional inverse Fourier It is a graph which shows the data obtained by performing conversion. As shown in FIG. 22 (c), by performing the above-described processing, data that has been subjected to a low-pass filter is obtained.

  In FIGS. 22B and 22C, data for one line in the x direction is shown for the sake of simplicity, but this is performed for each line in the x direction and each line in the y direction by two-dimensional Fourier transform. is there. In this embodiment, Fourier transform is used. However, the present invention is not limited to this, and other conversion formulas such as digital cosine transform may be used.

  By performing such processing, it is possible to obtain the distribution in the display screen of the liquid crystal display device itself excluding the spot component (display unevenness component).

By the same method, from the measured data of V255,
Llp (x, y, 255)
Ask for.

By the way, since the luminance of each pixel of the liquid crystal display panel can only take a value between the luminance of V0 and the luminance of V255, Llp calculated by the above method is a range between the luminance of V0 and the luminance of V255. If it is outside, it is necessary to correct the calculated Llp. That is, if all the coordinates (x, y) satisfy the following expression, there is no need for correction, but if the following expression is not satisfied, it is necessary to correct the calculated Llp so that it falls within the following expression.
Llp (x, y, 0) ≧ Lmeasure (x, y, 0)
Llp (x, y, 255) ≦ Lmeasure (x, y, 255)
Here, the comparison is made only with V0 and V255 because the relationship between the gradation luminances monotonously increases.

The corrected luminance ratio Llp ′ is calculated from the following values, where the minimum value of all coordinates (x, y) is Min () and the maximum value is Max ().
Llp ′ (x, y, 0) = Max (Lmeasure (x, y, 0) / Llp (x, y, 0)) × Llp (x, y, 0)
Llp ′ (x, y, 255) = Min (Lmeasure (x, y, 255) / Llp (x, y, 255)) × Llp (x, y, 255)
Since the gradation luminance characteristic is designed to be γ = 2.2, the luminance ratio Llp ′ other than V0 and V225 is as follows.
Llp ′ (x, y, t) = Llp ′ (x, y, 0) + (Llp ′ (x, y, 255) −Llp ′ (x, y, 0)) × (t / 255) ^2.2
In addition, if spot correction (display unevenness correction) is performed with 256 gradations, there is a concern about the occurrence of gradation skipping, and the brightness level of the spots (display unevenness) is finer than 256 gradations. Then, the pseudo gradation generation unit 18 uses a pseudo gradation technique such as FRC (frame rate control) to increase the number of gradation steps in a pseudo manner.

For example, when the gradation is expanded from 256 gradations to 1020 gradations by FRC, the gradation luminance ratio Lm_1020 after the expansion is as follows.
When tm = 0, 4,..., 1020,
Lm — 1020 (x, y, tm) = Lmeasure (x, y, tm / 4)
In the case of tm = 1, 5,.
Lm — 1020 (x, y, tm) = Lmeasure (x, y, (tm−1) / 4) × 0.75 + Lmeasure (x, y, (tm + 3) / 4) × 0.25
In the case of tm = 2, 6,.
Lm — 1020 (x, y, tm) = Lmeasure (x, y, (tm−2) / 4) × 0.5 + Lmeasure (x, y, (tm + 2) / 4) × 0.5
In the case of t = 3, 7,.
Lm — 1020 (x, y, tm) = Lmeasure (x, y, (tm−3) / 4) × 0.25 + Lmeasure (x, y, (tm + 1) / 4) × 0.75
The pseudo gradation generation unit 18 sets the gradation t of the coordinates (x, y) in the correction data input from the correction calculation unit 14 to a gradation value that is closest to the luminance value subjected to the low-pass filter process. Then, a conversion table (correction data) for converting to the following gradation tm is generated.
tm = Lm ^— 1020 ⁻¹ (x, y, Llp ′ (x, y, t (x, y)))
Here, Lm ^— 1020 ⁻¹ () is an inverse function related to tm.

  Note that since this is performed in units of divided sub-pixels, the maximum value of y is 1080 × 2 = 2160.

For example, in the case of measurement data when a bright division subpixel is arranged on the upper side and a dark division subpixel is arranged on the lower side, a conversion table of data when a gradation t is input to the coordinates (x, y) is It becomes street.
Bright division subpixel side;
tm = Lm ^— 1020 ⁻¹ (x, 2y, Llp ′ (x, y, tH (x, y)))
Dark sub-pixel side;
tm = Lm ^— 1020 ⁻¹ (x, 2y + 1, Llp ′ (x, y, tL (x, y)))
In addition, in the case of measurement data when the dark division subpixel is arranged on the upper side and the light division subpixel is arranged on the lower side, the conversion table of the data when the gradation t is input to the coordinates (x, y) is as follows: It becomes street.
Bright division subpixel side;
tm = Lm ^— 1020 ⁻¹ (x, 2y + 1, Llp ′ (x, y, tH (x, y)))
Dark sub-pixel side;
tm = Lm ^— 1020 ⁻¹ (x, 2y, Llp ′ (x, y, tL (x, y)))
Note that the conversion table (correction data) for converting from t to tm differs depending on the individual liquid crystal display panel. Therefore, the conversion table (correction table) generated for each liquid crystal display panel is generated and stored in the divided LUT 17. That is, tL (t) and tH (t) in the divided LUT 17 are set to tH (t) = t and tL (t) = t in the division LUT 17 at the time of measurement data acquisition, but during normal driving (correction for correcting display unevenness) In the case of performing display based on the subsequent video signal), the conversion table of the division LUT 17 is set to the display unevenness correction conversion table (correction data) generated as described above.

  Thereafter, correction data (correction value Lmura) for reducing display unevenness is calculated regardless of the viewing angle θ by the same method as described in the first embodiment, and is stored in the storage unit 15.

(1-4. Correction of input video signal)
When the video signal is corrected and displayed using the conversion table generated as described above, first, the subpixel division unit 16 divides the video signal for each subpixel based on the conversion table stored in the division LUT 17. The image signal is divided into image signals for each pixel and output to the correction calculation unit 14.

  The correction calculation unit 14 corrects the video signal input from the sub-pixel dividing unit 16 based on the correction data stored in the storage unit 15 and outputs the corrected video signal to the pseudo gradation generation unit 18.

  The pseudo gradation generation unit 18 performs pseudo gradation generation processing on the video signal input from the correction calculation unit 14 and outputs the result to the subpixel rearrangement unit 19.

  The subpixel rearrangement unit 19 rearranges the data of each divided subpixel according to the wiring on the TFT glass side of the liquid crystal display panel 10 and outputs the rearranged data to the liquid crystal controller 13.

  The above processing is performed for each color component of all pixels. In the case of correcting luminance unevenness (luminance unevenness), the luminance components of all pixels are corrected.

  The liquid crystal controller 13 controls the operation of the gate driver 11 and the source driver 12 based on the data for each divided subpixel input from the subpixel rearrangement unit 19, and displays an image corresponding to the video signal on the liquid crystal display panel 10. Let

  Thereby, in this embodiment, display unevenness can be appropriately corrected even when the liquid crystal display panel 10 is viewed from an oblique direction by individually controlling the applied voltage of each divided sub-pixel based on the correction data. . That is, in the conventional technique, when the display screen is viewed from an oblique direction, display unevenness has occurred due to the difference in viewing angle characteristics between the bright divided subpixels and the dark divided subpixels. Unevenness can be suppressed regardless of the viewing angle direction.

  In this embodiment, correction data is generated based on a measurement result when each divided subpixel is driven with the same input gradation voltage, and the input video signal is corrected using the generated correction data. As a result, correction data is not generated from apparent measurement data as in the prior art, but can be corrected according to the actual operation, so that the accuracy of correction when viewed obliquely is improved. Can do.

[Embodiment 3]
Still another embodiment of the present invention will be described. For convenience of explanation, members having the same functions as those in the above-described embodiment are denoted by the same reference numerals, and description thereof is omitted.

  The liquid crystal display device 1b according to the present embodiment has substantially the same configuration as that of the second embodiment except that the wiring structure of the liquid crystal display panel 10 is different.

  FIG. 23 is an explanatory diagram showing a schematic configuration of the TFT glass substrate 31 in the liquid crystal display panel 10 according to the present embodiment.

  In the second embodiment, two gate bus lines g and one source bus line s are provided for one subpixel, and two divided subpixels corresponding to one subpixel are sequentially driven. The configuration has been described.

  On the other hand, as shown in FIG. 23, the liquid crystal display panel 10 according to the present embodiment is provided with one gate bus line g and two source bus lines s for one subpixel. In addition, two divided subpixels corresponding to one subpixel are simultaneously driven, and different voltages are applied to the divided subpixels via different source bus lines s.

  That is, in the liquid crystal display panel 10 according to the present embodiment, as shown in FIG. 23, the source bus line s 6 times the number of display pixels in the horizontal direction (longitudinal direction) and the display pixels in the vertical direction (short direction). The same number of gate bus lines g are provided. For example, when the liquid crystal display panel 10 is an FHD (display pixel number: 1920 × 1080), the number of source bus lines s is 1920 × 3 × 2 = 111520, and the number of gate bus lines g is 1080. .

  Thus, by selecting one gate bus line g, six divided sub-pixels (22Ra, 22Rb, 22Ga, 22Gb, 22Ba, 22Bb) included in one pixel are driven simultaneously.

  FIG. 24A shows the input video signals r (x, y), g (x, y), and b (x, y) for each sub-pixel input to the sub-pixel dividing unit 16. ) Is a corrected video signal RH (x, y), RL (x, y), GH (x, y), GL (x, y), BH (x, y) for each divided sub-pixel corrected by the correction calculation unit 14. y), BL (x, y), and (c) shows output signals RH (x, y), RL (x, y), GH (x, y) from the sub-pixel rearrangement unit 19 to the liquid crystal controller 13. y), GL (x, y), BH (x, y), and BL (x, y) are shown.

  As shown in FIG. 24 (c), in this embodiment, when a certain gate bus line g is selected, the sub-pixel rearrangement unit 19 uses each divided sub-pixel of the pixel corresponding to the gate bus line g ( RH, RL, GH, GL, BH, and BL) are rearranged so that the electric potential according to the video signal is applied, and the data of the divided sub-pixels are rearranged and output to the liquid crystal controller 13.

  Thereby, in addition to the effects obtained by the configuration shown in the second embodiment, the following advantageous effects can be obtained. That is, in the configuration of the second embodiment, a storage unit such as a line memory is necessary to rearrange the data of each divided subpixel as shown in FIG. In the embodiment, since no storage means such as a line memory is required, the circuit configuration can be simplified and the device cost can be reduced.

  In addition, since the number of gate bus lines g can be halved in the configuration of the second embodiment, the write time (high-level pulse width) per gate bus line can be set higher than that of the second embodiment. Can also be long. As described above, the charging of the liquid crystal capacitor CL and the auxiliary capacitor C is performed during a period in which the gate bus line potential is at a high level. can do. Since the current value can be reduced, the size of the TFT 51 can be reduced. Moreover, since the TFT does not transmit light, the aperture ratio of the liquid crystal display panel 10 can be improved by reducing the size of the TFT 51.

  However, in the configuration of this embodiment, the number of outputs of the source driver 12 (the number of source bus lines s) is twice that of the configuration shown in the second embodiment, so the cost of the source driver 12 is shown in the second embodiment. Higher than the configuration. In general, the source driver has a more complicated circuit configuration than the gate driver, and the cost of the source driver per source bus line may be higher than the cost of the gate driver per gate bus line. Many.

[Embodiment 4]
Still another embodiment of the present invention will be described. For convenience of explanation, members having the same functions as those in the above-described embodiment are denoted by the same reference numerals and description thereof is omitted.

  FIG. 25 is an explanatory diagram showing a schematic configuration of the liquid crystal display device 1c according to the present embodiment. As shown in this figure, the liquid crystal display device 1c according to the present embodiment includes a correction data expansion unit 71 in addition to the configuration of the liquid crystal display device 1b according to the second and third embodiments. In the present embodiment, correction data for correcting display unevenness stored in the storage unit 15 is compressed and stored. The correction data decompression unit 71 decompresses the compressed correction data stored in the storage unit 15 and outputs the decompressed correction data to the correction calculation unit 14.

  In the division LUT 17 used to divide the sub-pixel gradation t into the division sub-pixel gradations tL and tH when the division sub-pixel drive is performed, the gradation of the bright division sub-pixel and the gradation of the dark division sub-pixel Are set so as not to use as much as possible the gradation of the halftone portion having poor viewing angle characteristics. For this reason, there are gradations that are not used in each divided sub-pixel. Therefore, there is no problem even if the correction data of unused gradation is not included in the correction data stored in the storage unit 15. Therefore, in the present embodiment, the correction data is compressed by omitting the correction data of the gradation that is not used at the time of driving the divided subpixels from the correction data created by the same method as in the first embodiment, and the compressed correction data is stored. Stored in the unit 15.

  FIG. 26 is an example of a frequency distribution table of gradations used in correction data after compression. That is, FIG. 26 shows the frequency of gradation used as the gradation of the divided subpixel in the divided video signal obtained by dividing the video signal of the subpixel into the video signal of the divided subpixel. Note that gradations not shown in this figure are not used as the gradations of the divided sub-pixels.

  In the case of the example of FIG. 26, the total number of gradations used at tH and tL is 246 gradations. Since the number of gradations before compression is 255, the correction data size can be reduced by omitting gradation correction data that is not used in each divided sub-pixel as in the present embodiment.

  Thereby, even when a liquid crystal display panel similar to the above-described embodiment is viewed from an oblique direction, display unevenness can be corrected appropriately, and the data size of correction data stored in the storage unit 15 can be reduced. it can. Further, by reducing the data size of the correction data, it is possible to reduce the data bus necessary for transferring the correction data.

  In addition, since the gradation to be used is different between the dark division sub-pixel and the light division sub-pixel, for example, when using the correction data of two pixels on an average basis, between the bright division sub-pixels of the same color in adjacent pixels You may use the combination corresponding to the result of averaging the gradation and the gradation of the dark division subpixels of the same color.

[Embodiment 5]
Still another embodiment of the present invention will be described. For convenience of explanation, members having the same functions as those in the above-described embodiment are denoted by the same reference numerals and description thereof is omitted.

  FIG. 27 is an explanatory diagram showing a schematic configuration of the liquid crystal display device 1d according to the present embodiment. As shown in this figure, the liquid crystal display device 1d includes a liquid crystal display panel 10, a gate driver 11, a source driver 12, a liquid crystal controller 13, a correction calculation unit 14, a storage unit 15, a pseudo gradation generation unit 18, a gradation DAC ( A gradation digital-to-analog converter) 81 and a regulator 82.

  The storage unit 15 stores correction data for correcting display unevenness of the liquid crystal display panel 10 in advance. Since the correction data differs depending on the individual liquid crystal display panel, the correction data is generated from the display unevenness information of each liquid crystal display panel, and is written to the storage unit 15 from the outside. The correction data is set for each subpixel and for each gradation.

  The correction calculation unit 14 corrects the subpixel data in the input video signal based on the correction data stored in the storage unit 15 so that the display unevenness of the liquid crystal display panel 10 is less visible.

  The pseudo gradation generation unit 18 performs a pseudo gradation generation process for expressing the display image with a greater number of gradations than the number of gradations of the video signal.

  The liquid crystal controller 13 generates a control signal for operating the gate driver 11, the source driver 12, and the gradation DAC 81 of the liquid crystal display panel 10 based on the corrected video signal, and transmits the control signal to these units.

  The gradation DAC 81 outputs a reference potential (gradation reference potential) for determining the output voltage of the source driver 12.

  The regulator 82 generates a potential serving as a reference for the gradation DAC 81.

  The source driver 12 applies a potential corresponding to the input signal from the liquid crystal controller 13 and the voltage value supplied from the gradation DAC 81 to each source bus line s of the liquid crystal display panel 10.

  The gate driver 11 sequentially applies a voltage to each gate bus line g of the liquid crystal display panel 10 at a timing according to an input signal from the liquid crystal controller 13.

  FIG. 28 is an explanatory diagram showing a schematic configuration of the TFT glass substrate 31 in the liquid crystal display panel 10. As shown in this figure, in the present embodiment, a liquid crystal display panel 10 similar to the configuration shown in FIG. 9 is used. In this embodiment, for convenience of explanation, the source bus line s is referred to as SZ0, SY0, SX0, SX1, SY1, SX1,. The gate bus line g is referred to as G0, G1, G2,..., G2159 in order from the side closer to the source driver 12 (upper side in the figure).

  FIG. 29 is an explanatory diagram showing a configuration example of the gradation DAC 81. As shown in this figure, the grayscale DAC 81 includes two nonvolatile memories (reference potential storage units) BANK_A and BANK_B, a switcher MUX, a memory M, a D / A (digital / analog) converter DAC, and an amplifier. A.

  The non-volatile memories BANK_A and BANK_B each store 18 types of output voltage setting information. 30A shows output voltage setting information stored in the nonvolatile memory BANK_A, and FIG. 30B shows output voltage setting information stored in the nonvolatile memory BANK_B. Yes. The potentials stored in the nonvolatile memories BANK_A and BANK_B are set based on the result of measuring the luminance of the display screen on which the measurement image is displayed in advance so that the error due to the viewing angle becomes small.

  The switcher MUX switches the non-volatile memory used for setting the output voltage to BANK_A or BANK_B based on the BANK_SEL signal input from the liquid crystal controller 13. That is, the non-volatile memory to be used is switched so that the non-volatile memory BANK_A is used when driving the dark division subpixel and the non-volatile memory BANK_B is used when driving the bright division subpixel.

  When the number of divided subpixels is two, at least two nonvolatile memories BANK are necessary, but the number is not limited to two, and three or more nonvolatile memories may be provided. For example, a nonvolatile memory BANK may be provided for each source bus line or for each source bus line group composed of a plurality of source bus lines, and γ may be adjusted according to the position and degree of display unevenness.

  The memory M temporarily stores information DATA0 to DATA17 selected by the switcher MUV.

  The D / A converter DAC outputs a voltage corresponding to the information DATA0 to DATA17 stored in the memory M.

Specifically, when the reference voltage VREFIN is input from the regulator 82 to the D / A converter DAC, and the D / A converter DAC is a 10-bit D / A converter,
OUTn = 0 (GND) + DATAn / 1023 × (VREFIN−0 (GND))
The output voltage is set based on Note that n = 0, 1, 2,..., 17 (integers from 0 to 17).

  The amplifier A amplifies and outputs the output voltage from the D / A converter DAC.

  Note that the data of the nonvolatile memory BANK may be provided outside (for example, the correction calculation unit 14 or the liquid crystal controller 13), and information DATA0 to DATA17 may be directly written in the memory M.

  FIG. 31 is an explanatory diagram illustrating a configuration of a connection portion between the source driver 12 and the liquid crystal display panel 10. As shown in this figure, the source driver 12 is composed of a plurality of source drivers 12a, 12b,.

  VH255,..., VH0, VL0,..., VL255 are called gradation reference power supplies (gradation reference potentials), and are supplied from output terminals OUT0. LV0,..., LV5 are signals representing image data sent from the liquid crystal controller 13. LBR is a signal for setting the shift direction of the source driver 12, and is used for left-right inversion of the shift direction. In this embodiment, for simplification, the shift direction is fixed, and LBR is always at a high level. LS is a latch pulse signal that defines the output timing of the source driver 12, REV is a signal for controlling polarity inversion, CLK is a clock signal, and SSP is a start pulse signal that represents the start point of data. .

  The source driver 12 supplies a voltage corresponding to the gradation reference potential and each signal to the source bus line s of the liquid crystal display panel 10. In this embodiment, the source drivers 12a, 12b,..., 12f supply voltages to 960 source bus lines s, respectively.

  FIG. 32 is an explanatory diagram showing the configuration of the source drivers 12a to 12f. As shown in this figure, the source drivers 12a to 12f include a comparator 91, a data latch & serial / parallel converter 92, a shift register 93, a sampling memory 94, a hold memory 95, a level shifter 96, a reference voltage generation circuit 97, and a DA converter. 98, and an output circuit 99.

  The comparator 91 receives the clock signal CLK and the image data LV0,..., LV5 from the liquid crystal controller 13, and the comparator 91 converts the image data LV0,. Level) and output to the data latch & serial / parallel converter 92 and the clock signal CLK to the data latch & serial / parallel converter 92 and shift register 93. Note that the comparator 91 is not an essential component and may be omitted.

  The data latch & serial / parallel conversion unit 92 temporarily latches the input image data, converts the image data from serial to parallel, and outputs it to the sampling memory 94.

  The shift register 93 is a bidirectional shift register, performs a shift operation according to the clock signal CLK, and selects a bit for sampling image data.

  The sampling memory 94 samples image data input in a time division manner.

  The hold memory 95 collectively latches the image data sampled by the sampling memory 94 according to the latch pulse LS.

  The level shifter 96 shifts the image data latched by the hold memory 95 to the analog circuit unit power level and sends it to the DA converter 98.

  The reference voltage generation circuit 97 is based on the gradation reference potentials (VH255,..., VH0, VL0,..., VL255; see FIG. 30) input from the gradation DAC 81, and based on the arithmetic expression shown in FIG. A potential between reference potentials (in this embodiment, 256 gradations) is calculated. In FIG. 33, some arithmetic expressions of 246 gradations are extracted and described, but in reality, all 256 gradations are calculated.

  The DA converter 98 generates an analog signal corresponding to the image data and sends it to the output circuit 99. Specifically, the DA converter 98 selects VHn or VLn (n = 0 to 255) in FIG. 33 with reference to the REV signal, and responds to the image data based on the voltage calculated by the reference voltage generation circuit 97. Select the correct voltage.

  The output circuit 99 is a voltage follower composed of an operational amplifier and an output buffer, and outputs 256 gradations × 2 types of analog signals to 960 liquid crystal drive output terminals. FIG. 34 is a voltage luminance ratio curve of the liquid crystal showing the luminance ratio with respect to the voltage applied to the divided subpixels.

  FIG. 35 is an explanatory diagram showing voltage waveforms supplied to the divided sub-pixels.

  The gate bus line potential is the potential of the gate bus line g connected to the gate of the TFT 51 of the divided subpixel. When this potential becomes higher than the potential of the source bus line s, the TFT 51 is turned on (opened) and the source terminal And a current flows between the drain terminal. As a result, the source bus line potential is applied to the pixel electrode 34, and the liquid crystal capacitor CL and the auxiliary capacitor C are charged. The potential of the auxiliary capacitor C is held while the TFT 51 is off, and the potential difference between the pixel electrode 34 and VCOM becomes constant, and the electric field applied to the liquid crystal is maintained during that time.

  After the TFT 51 is turned off, it is the next frame that is turned on next. In FIG. 35, the source bus line potential and the pixel electrode potential in the next frame are made lower than VCOM because if the potential is continuously applied to the liquid crystal in a certain direction, burn-in may occur due to the influence of impurities contained in the liquid crystal material. This is because the direction in which the electric field is applied is reversed (inverted) every frame in order to boil. In the following description, potentials higher than VCOM applied to the source bus line s are VH0, VH1,..., VH255 for each gradation, and potentials lower than VCOM are VL0, VL1,. And

  A control signal rev (see FIGS. 31 and 32) input from the liquid crystal controller 13 to the source drivers 12a to 12f is a signal for controlling the polarity inversion of the potential applied to the source bus line s. By switching between the high level and the low level, as shown in FIG. 36, the polarity of each divided sub-pixel (the polarity with respect to the counter electrode potential VCOM) is controlled to be inverted every frame.

  FIG. 37 is an explanatory diagram showing waveforms of drive signals for the liquid crystal display panel 10. Note that the data sequence is input in order from the top.

  SSP is a start pulse of image data for each gate bus line, and image data of each pixel is input to the source driver 12 immediately after the start pulse is input.

  When a latch pulse LS is input after image data for one gate bus line is input, output to each source bus line s is performed based on the image data input immediately before. At this time, the BANK_SEL input from the liquid crystal controller 13 to the gradation DAC 81 changes between the latch pulse LS and the next latch pulse LS, so that the output based on BANK_A and the output based on BANK_B are switched. As a result, two types of outputs can be performed: the output DLn for the dark division subpixel and the output DHn for the bright division subpixel. On the other hand, on the gate driver side, the gate bus line g for outputting a high level signal is sequentially shifted regardless of changes in DL and DH. As a result, display can be performed for each divided sub-pixel.

  FIG. 38 is a graph showing the viewing angle characteristics of the liquid crystal display device 1d according to the present embodiment. 39A is a graph showing viewing angle characteristics in a comparative example in which the liquid crystal display device 1d is driven with only one type of nonvolatile memory BANK of the grayscale DAC 81 as shown in FIG. 39B. FIGS. 38 and 39 each show an example in which a CSP type liquid crystal display panel is used. In the case of the MVA type liquid crystal display panel, since the appearance changes depending on from which direction it is viewed, it is necessary to add a parameter φ indicating from which direction as in the first embodiment.

  As shown in FIG. 38, in the liquid crystal display device 1d of the present embodiment, the difference in the gradation luminance ratio curve between the front and the diagonal is smaller than that in FIG. Can be difficult.

  Next, a measurement process for creating correction data will be described.

  FIG. 40 shows setting data for the non-volatile memories BANK_A and BANK_B of the grayscale DAC 81 used for measurement display performed when creating correction data. By performing display using the data of the nonvolatile memories BANK_A and BANK_B shown in FIG. 40A, the same voltage as that of the dark division subpixel is applied to all the division subpixels. Thereby, the measurement of the dark division subpixel can be performed.

  Similarly, by performing display using the data of the nonvolatile memories BANK_A and BANK_B shown in FIG. 40B, the same voltage as in the case of the bright division subpixel is applied to all the division subpixels. Thereby, the measurement of the bright division subpixel can be performed.

  Based on the measurement data thus measured, a correction value is generated by a method similar to that of the second embodiment (a method of performing low-pass filter processing using Fourier transform).

  As a result, the correction values of the bright and dark division subpixels are obtained for all the subpixels.

  As described above, in this embodiment, correction data is generated based on a measurement result when each divided sub-pixel is driven with the same input gradation voltage, and the input video signal is corrected using the generated correction data. . As a result, correction data is not generated from apparent measurement data as in the prior art, but can be corrected according to the actual operation, so that the accuracy of correction when viewed obliquely is improved. Can do.

  In the present embodiment, two types of reference voltages for the grayscale DAC 81 are prepared (nonvolatile memories BANK_A and BANK_B), and the reference voltage used in the bright division subpixel and the dark division subpixel is switched to thereby reduce the dark voltage. The potential applied to the divided subpixel and the bright divided subpixel is changed. In addition, the above-described two types of reference voltages are set so that the bright reference subpixel and the dark reference subpixel corresponding to each gradation are set to the same reference voltage, and a measurement image (solid image) is displayed. Based on the measurement result of the displayed display screen, settings are made so that the viewing angle characteristics can be improved. Thereby, it is possible to improve the viewing angle characteristics when displaying a video corresponding to the input video data.

[Embodiment 6]
Still another embodiment of the present invention will be described. For convenience of explanation, members having the same functions as those in the above-described embodiment are denoted by the same reference numerals and description thereof is omitted.

  FIG. 41 is an explanatory diagram showing a schematic configuration of the liquid crystal display device 1e according to the present embodiment. As shown in this figure, the liquid crystal display device 1e includes a liquid crystal display panel 10, a gate driver 11, a source driver 12, a liquid crystal controller 13, a correction calculation unit 14, a storage unit 15, a pseudo gradation generation unit 18, a gradation DAC ( A gradation digital-to-analog converter) 81b, a regulator 82, a CS power supply circuit 83, a VCOM power supply circuit 84, and a switching circuit (SW) 85.

  The storage unit 15 stores correction data for correcting display unevenness of the liquid crystal display panel 10 in advance. Since the correction data differs depending on the individual liquid crystal display panel, the correction data is generated from the display unevenness information of each liquid crystal display panel, and is written to the storage unit 15 from the outside. The correction data is set for each subpixel and for each gradation.

  The correction calculation unit 14 corrects the subpixel data in the input video signal based on the correction data stored in the storage unit 15 so that the display unevenness of the liquid crystal display panel 10 is less visible.

  The pseudo gradation generation unit 18 performs a pseudo gradation generation process for expressing the display image with a greater number of gradations than the number of gradations of the video signal.

  The liquid crystal controller 13 generates a control signal for operating the gate driver 11, the source driver 12, and the CS power supply circuit 83 of the liquid crystal display panel 10 based on the corrected video signal, and transmits the control signal to these units.

  The regulator 82 generates a potential serving as a reference for the gradation DAC 81b, the VCOM power supply circuit 84, and the CS power supply circuit 83.

  The gradation DAC 81b outputs a reference potential (gradation reference potential) for determining the output voltage of the source driver 12. In the present embodiment, the gradation DAC 81b outputs 18 kinds of gradation reference potentials similar to those in FIG.

  The source driver 12 applies a potential corresponding to the input signal from the liquid crystal controller 13 and the voltage value supplied from the gradation DAC 81 b to each source bus line s of the liquid crystal display panel 10.

  The VCOM power supply circuit 84 is a circuit that generates a voltage to be applied to the counter electrode 35 provided on the CF glass substrate 32 of the liquid crystal display panel 10. The potential applied to the counter electrode 35 is supplied to the liquid crystal display panel 10 via the source driver 12.

  The CS power supply circuit 83 is a circuit that generates a voltage to be supplied to the CF side electrode (auxiliary capacitance line CS) in the auxiliary capacitance C of the divided subpixel of the liquid crystal display panel 10. The potential supplied to the storage capacitor line CS is supplied to the liquid crystal display panel 10 via the switching circuit 85 and the source driver 12.

  The switching circuit 85 is a switch for switching the output voltage between a voltage (VCOM voltage) output to the counter electrode wiring 52 and a voltage (CS voltage) output to the auxiliary capacitance wiring CS.

  The gate driver 11 sequentially applies a voltage to each gate bus line g of the liquid crystal display panel 10 at a timing according to an input signal from the liquid crystal controller 13.

  FIG. 42 is an explanatory diagram showing a wiring structure of the TFT glass substrate 31 and the CF glass substrate 32 in the liquid crystal display panel 10. FIG. 43 is an equivalent circuit diagram of each subpixel 21 in the liquid crystal display panel 10.

  As shown in FIG. 42, the TFT glass substrate 31 includes a number of source bus lines s extending in the vertical direction (y-axis direction; the short direction of the rectangular liquid crystal display device 10) and the horizontal direction (x-axis direction). A large number of gate bus lines g extending in the longitudinal direction of the rectangular liquid crystal display device 10. Each gate bus line g is connected to the gate driver 11, and each source bus line s is connected to the source driver 12.

  The number of source bus lines s is three times the number of display pixels in the horizontal direction (x-axis direction) (1920 × 3 = 5760 in the case of FHD), and the number of gate bus lines g is vertical (y-axis). (The direction) is the same as the number of display pixels (1080 for FHD). In the present embodiment, for convenience of explanation, each source bus line s is referred to as SZ0, SY0, SX0, SZ1, SY1, SX1,. Each gate bus line g is referred to as G0, G1, G2,..., G1079 in order from the source driver 12 side.

  As shown by a broken line in FIG. 42, the end of the CF glass substrate 32 on the gate driver 11 side is along the longitudinal direction (y-axis direction) of the liquid crystal display panel 10, one end of which is connected to the source driver 12. A plurality (12 in this embodiment) of auxiliary capacity trunk lines (bundles of auxiliary capacity lines) CSt extending are arranged. Further, each of the auxiliary capacity trunk lines CSt is connected with an auxiliary capacity line CS extending in the horizontal direction (x direction) of the liquid crystal display panel 10.

  In the present embodiment, the storage capacitor trunk line CSt is referred to as CSt0, CSt1,..., CSt11 in order from the gate driver 11 side, and each storage capacitor line CS is referred to as CS0, CS1,. . The auxiliary capacitance lines CS0, CS1,..., CS11 are connected to the auxiliary capacitance trunk lines CSt0, CSt1,. That is, the storage capacitor line CS0 is connected to the storage capacitor trunk line CSt0, the storage capacitor line CS1 is connected to the storage capacitor trunk line CSt1, and the storage capacitor line CS11 is connected to the storage capacitor trunk line CSt11. Further, a plurality of storage capacitor wiring groups each including 12 storage capacitor lines CS0, CS1,..., CS11 are arranged along the vertical direction (y-axis direction) of the liquid crystal display panel 10. That is, the auxiliary capacitance wiring CS0 of the next auxiliary capacitance wiring group is arranged at a position adjacent to the auxiliary capacitance wiring CS11 of a certain set of auxiliary capacitance wiring group in the vertical direction.

  The source bus line s and the gate bus line g are arranged in a lattice pattern, and two TFTs 51 are arranged at the upper and lower sides of the gate bus line g at each intersection. The source terminal 51s of the TFT 51 is connected to the source bus line s, the gate terminal 51g is connected to the gate bus line g, and the drain terminal 51d is connected to the pixel electrode 34 of the divided subpixel 22a or 22b. That is, in the present embodiment, the divided subpixels 22a and 22b of each subpixel 21 are connected to a common gate bus line g.

  The TFT 51 is provided as a switching element for each divided sub-pixel. When the potential of the gate bus line g is higher than the potential of the source bus line s to which the TFT 51 is connected, the switch is turned on and the pixel electrode 34 is turned on. Is applied with the potential of the source bus line s.

  As shown in FIG. 43, the counter electrode 35 of each of the divided sub-pixels 22a and 22b is connected to the counter electrode wiring 52, and a counter voltage VCOM is applied to each counter electrode 35. Further, auxiliary capacitance lines CSn and CSn + 1 are arranged at positions corresponding to the divided sub-pixels 22a and 22b on the CF glass substrate 32, respectively. In the divided sub-pixel 22a, between the pixel electrode 34 and the auxiliary capacitance line CSn. The auxiliary capacitance C is formed, and the auxiliary capacitance C is formed between the pixel electrode 34 and the auxiliary capacitance line CSn + 1 in the divided sub-pixel 22b.

  FIG. 44 is an explanatory diagram showing the configuration of the VCOM power supply circuit 84. As shown in this figure, the VCOM power supply circuit 84 includes a nonvolatile memory 101, a DAC 102, and an amplifier 103.

  The nonvolatile memory 101 stores potential setting information VCOM_DATA indicating a VCOM potential (counter electrode potential) set for each liquid crystal display panel.

A DAC (digital analog converter) 102 generates a VCOM potential based on a reference voltage VREFIN input from the outside and potential setting information VCOM_DATA stored in the nonvolatile memory 101. Specifically, the DAC 102
VCOM = VREFIN × VCOM_DATA / 1023
A VCOM potential is generated based on

  The amplifier 103 amplifies the output potential of the DAC 102 and outputs it to the source driver 12, the CS power supply circuit 83, and the switching circuit 85.

  FIG. 45 is an explanatory diagram showing the configuration of the CS power supply circuit 83. As shown in this figure, the CS power supply circuit 83 includes a power supply circuit 104 and switches 105a to 105f.

  The power supply circuit 104 generates two types of power supply voltages A and B based on a reference potential VREFIN input from the outside and a VCOM potential input from the VCOM power supply circuit 84.

  The output of the CS power supply circuit 83 is a vibration power supply. Of the above two types of power supply voltages A and B, the power supply voltage A is a power supply for generating a potential on the upper side (high potential side) of the vibration power supply. B is a power source for creating a lower (low potential) potential. Note that the DC component of the output of the CS power supply circuit 83 is set to be the VCOM potential. The time for applying the power supply voltages A and B is not particularly limited, and may be set as appropriate according to the characteristics of the liquid crystal display panel 10 and the like.

If the amplitude of the output waveform of the CS power supply circuit 83 is CS_AC, the potentials of the power supply voltages A and B are
A = VCOM + CS_AC / 2
B = VCOM-CS_AC / 2
It is represented by

  Note that the amplitude CS_AC of the output waveform of the CS power supply circuit 83 depends on the auxiliary capacitor C and the like, and is set to an optimum value for each liquid crystal display panel. Also, the application time is set so that the viewing angle characteristic is appropriate.

  The switches 105a to 105f include two input terminals to which power supply voltages A and B output from the power supply circuit 104 are input, two output terminals OUTi-1 and OUTi (i is an odd number from 1 to 11), and liquid crystal And a control terminal to which control signals SEL0 to SEL5 are input from the controller 13. The switches 105a to 105f output the power supply voltage A from the output terminal OUTi-1 and the power supply voltage B from the output terminal OUTi when the control signals SEL0 to SEL5 are 0. When the control signals SEL0 to SEL5 are 1, the switches 105a to 105f output the power supply voltage A from the output terminal OUTi and output the power supply voltage B from the output terminal OUTi-1. As a result, the power supply voltage A is supplied to the auxiliary capacitance line CS of the bright division subpixel, and the power supply voltage B is supplied to the auxiliary capacitance line CS of the dark division subpixel.

The output terminals OUT0 to OUT11 of the switches 105a to 105f and the auxiliary capacitance lines CS0 to CS11 of the liquid crystal display panel 10 are
CS0 = OUT0, CS1 = OUT1,... CS11 = OUT11
It is connected to become.

  FIG. 46 is an explanatory diagram showing a configuration example of the gradation DAC 81b. As shown in this figure, the gradation DAC 81 includes a nonvolatile memory (reference potential storage unit) BANK, a memory M, a D / A (digital / analog) converter DAC, and an amplifier A.

  The nonvolatile memory BANK stores 18 kinds of output voltage setting information DATA0 to DATA17.

  The memory M temporarily stores information DATA0 to DATA17 stored in the nonvolatile memory.

The D / A converter DAC outputs a voltage corresponding to the information DATA0 to DATA17 stored in the memory M. Specifically, when the reference voltage VREFIN is input from the regulator 82 to the D / A converter DAC, and the D / A converter DAC is a 10-bit D / A converter,
OUTn = 0 (GND) + DATAn / 1023 × (VREFIN−0 (GND))
The output voltage is set based on Note that n = 0, 1, 2,..., 17 (integers from 0 to 17).

  The amplifier A amplifies and outputs the output voltage from the D / A converter DAC.

  Note that the data in the memory BANK may be provided outside (for example, the correction calculation unit 14 or the liquid crystal controller 13), and information DATA0 to DATA17 may be directly written in the memory M.

  The switching circuit 85 outputs the VCOM voltage output from the VCOM power supply circuit 84 to the source driver 12 when measuring the display unevenness of the liquid crystal display panel 10, and at the time of normal image display (when the input video signal is corrected and displayed) ), The output voltage from the CS power supply circuit 83 is output to the source driver 12.

  In addition to the processing described in the fifth embodiment, the source driver 12 outputs a voltage corresponding to the video data input from the liquid crystal controller 13 and the gradation reference voltage input from the gradation DAC 81b to each source bus line s. To do. Since the method of generating the voltage supplied from the source driver 12 to each source bus line s is the same as in the fifth embodiment, the description thereof is omitted here.

  The source driver 12 outputs the VCOM voltage input from the VCOM power supply circuit 84 to the counter electrode 35 via the counter electrode wiring 52 and the CS voltage input via the switching circuit 85 (when measuring display unevenness). Is output to the auxiliary capacitance lines CS0 to CS11 via the auxiliary capacitance trunk lines CSt0 to CSt11.

  FIG. 47 shows voltage waveforms of the divided sub-pixels when the VCOM voltage is supplied to each auxiliary capacitance line CS. When the gate bus line potential becomes higher than the source bus line potential, the TFT 51 is turned on (opened), and a current flows between the source terminal and the drain terminal. Thus, the source bus line potential is applied to the pixel electrode 34 and the auxiliary capacitor C on the TFT glass substrate 31 side (pixel electrode 34), and the divided sub-pixels are charged. While the TFT 51 is OFF, the potential of the auxiliary capacitor C is maintained, the potential difference between the pixel electrode 34 and the counter electrode 35 (VCOM voltage) becomes constant, and the electric field applied to the liquid crystal is maintained. After the TFT 51 is turned off, it is the next frame that is turned on next. The source bus line potential in the next frame is lower than the counter electrode voltage VCOM. If the potential is continuously applied to the liquid crystal in a certain direction, image sticking or boiling occurs due to the impurities contained in the liquid crystal material. This is to reverse the direction in which the electric field is applied.

  Regarding the potential applied to the source bus line S, potentials higher than VCOM are VH0, VH1,..., VH255 for each gradation, and potentials lower than VCOM are VL0, VL1,.

  At this time, the potential applied to the source bus line S is higher than the ground (GND) potential in both cases of VH (VH0, VH1,..., VH255) and VL (VL0, VL1,..., VL255). As shown in FIG. 47, a phenomenon occurs in which the source bus line potential is drawn to the ground side. Thereby, the potential applied to the pixel electrode 34 is shifted. In order to correct this, the potential (counter electrode potential) applied to the counter electrode 35 provided on the CF glass substrate 32 is adjusted (counter electrode potential adjustment). The above pull-in phenomenon is caused by stray capacitance with respect to the ground potential, and thus varies depending on the individual liquid crystal display panel. Therefore, the value of the counter electrode potential VCOM is adjusted for each liquid crystal display panel.

  The non-volatile memory 101 of the VCOM power supply circuit 84 described above stores potential setting information VCOM_DATA indicating the VCOM potential (counter electrode potential) set by such counter electrode potential adjustment.

  Further, after adjusting the counter electrode potential, the switching circuit 85 is controlled to supply the VCOM voltage to each auxiliary capacitance line CS, and a measurement image (solid image) is displayed on each divided pixel. Similarly, the luminance of the display screen on which the measurement image is displayed is measured from a plurality of viewing angle directions. Based on the measurement result, correction data is generated and stored in the storage unit 15 by the same method as in the second embodiment.

  48A and 48B are explanatory diagrams showing drive voltage waveforms of the divided sub-pixels. FIG. 48A shows the drive voltage waveforms of the bright divided sub-pixels, and FIG. As described above, in the present embodiment, the voltage of the auxiliary capacitance line CS is set as the vibration voltage (vibration power supply). In addition, among the bipolar plates of the auxiliary capacitor C, the potential of the electrode plate on the TFT glass substrate 31 side (pixel electrode 34 side) is between the two plates of the auxiliary capacitor C when the potential of the auxiliary capacitor wiring CS changes. It changes so as to maintain the potential difference. Therefore, the potential of the pixel electrode 34 is changed by changing the potential of the storage capacitor line CS.

  In the present embodiment, since the CS power supply circuit 83 is a cross switch, the potential changes of the pixel electrodes 34 of the divided subpixels 22a and 22b constituting the subpixel 21 occur simultaneously. For this reason, the total luminance of both the divided sub-pixels 22a and 22b is constant even when the potential change of the pixel electrode 34 of each divided sub-pixel 22a and 22b occurs.

  With this operation, even when the source bus line potential applied to the source bus line s is the same, the charges charged in the liquid crystal capacitor CL and the auxiliary capacitor C are made different between the divided subpixel 22a and the divided subpixel 22b. Similarly to the second embodiment, divided sub-pixel driving can be realized.

  Note that the polarity of the voltage applied to each of the divided sub-pixels 22a and 22b (the polarity with respect to the counter electrode potential VCOM) is controlled so as to be inverted every frame, as in FIG.

  49 shows the VL (the source bus line potential is negative with respect to the counter electrode potential VCOM) in the bright divided subpixel and the dark divided subpixel when the amplitude CS_AC of the output waveform of the CS power supply circuit 83 is CS_AC = 0.2V. Potential difference between the pixel electrode 34 and the counter electrode 35 when set to be positive), VH (potential difference between the pixel electrode 34 and the counter electrode 35 when the source bus line potential is set to be positive with respect to the counter electrode potential VCOM) , And (VH−VL) / 2.

  FIG. 50A is a graph showing a gradation luminance ratio curve when the potential of the auxiliary capacitance line CS is changed as in the present embodiment, and FIG. 50B is a graph of the auxiliary capacitance line CS. It is a graph which shows the gradation luminance ratio curve when an electric potential is made constant with a counter electrode electric potential (comparative example).

  As shown in FIG. 50A, by changing the potential of the auxiliary capacitance line CS as in the present embodiment, the viewing angle characteristics when displaying an image according to the input image data can be improved. .

  In this embodiment, correction data is generated based on a measurement result when each divided subpixel is driven with the same input gradation voltage, and the input video signal is corrected using the generated correction data. As a result, correction data is not generated from apparent measurement data as in the prior art, but can be corrected according to the actual operation, so that the accuracy of correction when viewed obliquely is improved. Can do.

  41, the output of the CS power supply circuit 83 and the VCOM power supply circuit 84 is input to the switching circuit 85, and the voltage output from the switching circuit 85 to the auxiliary capacitance line CS is the output voltage from the CS power supply circuit 83. However, the present invention is not limited to this. For example, the reference potential VREFIN input to the power supply circuit 104 of the CS power supply circuit 83 may be switched to the VCOM voltage during measurement for generating correction data.

[Summary]
The liquid crystal display devices 1a to 1e according to the first aspect of the present invention include a liquid crystal display panel 10 including a plurality of picture elements (subpixels 21) including a plurality of divided picture elements (divided subpixels 22), and a level of an input video signal. A storage unit 15 that stores correction data set for each key and for each of the divided picture elements (divided subpixels 22), and corrects an input video signal based on the correction data so as to correct the divided picture elements (divided subpixels 22). ) For each corrected picture element (divided sub-pixel 22) according to the corrected video signal, and a driving unit (gate driver 11, source driver 12, liquid crystal) Controller 13), and the correction data is obtained based on the result of measuring the display characteristics of the liquid crystal display panel 10 displaying a predetermined measurement image from a plurality of viewing angles. It is characterized in that the display unevenness of the liquid crystal display panel 10 is viewing angle direction is generated correction data can be suppressed even if different.

  According to the above configuration, the display unevenness of the liquid crystal display panel 10 is suppressed even when the viewing angle directions are different based on the result of measuring the display characteristics of the liquid crystal display panel 10 displaying the measurement image from a plurality of viewing angle directions. The input video signal is corrected using the correction data generated as possible, and each divided picture element is driven based on the corrected video signal. As a result, display unevenness can be appropriately corrected regardless of the viewing angle direction.

  In the liquid crystal display devices 1b to 1e according to the second aspect of the present invention, the correction data of the liquid crystal display panel 10 when the same potential is applied to each of the divided picture elements (divided subpixels 22) in the first aspect. This is a configuration that is correction data set for each divided picture element (divided subpixel 22) based on the result of measuring display characteristics from a plurality of viewing angle directions.

  According to said structure, each division | segmentation pixel (division subpixel 22) is separately used using the correction data produced | generated based on the measurement result when the same electric potential is applied to each division | segmentation pixel (division subpixel 22). The display unevenness correction is appropriately performed regardless of the viewing angle direction without considering the difference in viewing angle characteristics of the two divided picture elements (divided subpixels 22) constituting the picture element (subpixel 21). Can be done.

  The liquid crystal display device 1b according to the third aspect of the present invention is the liquid crystal display device 1b according to the second aspect, wherein the driving unit (gate driver 11, source driver 12, liquid crystal controller 13) includes the gate driver 11 and the source driver 12, (Subpixel 21) is composed of two divided picture elements (divided subpixels 22), and the two divided picture elements (divided subpixels 22) constituting each picture element (subpixel 21) are connected to different gate bus lines g. The gate driver 11 sequentially selects the gate bus line g, and the source driver 12 selects the gate bus line g selected by the gate driver 11. For each divided picture element (divided subpixel 22) connected to the line via the source bus line s Serial is configured to apply a potential corresponding to the gradation of the divided picture elements in the corrected image signal (divided sub-pixels 22).

  According to the above configuration, in the liquid crystal display panel 10 in which the picture element (subpixel 21) is composed of a plurality of divided picture elements (divided subpixel 22), each divided picture element (divided subpixel 22) is individually driven. can do. Therefore, the same potential is applied to each divided picture element (divided subpixel 22) during measurement to generate correction data, and during normal display (when the input video signal is corrected and displayed according to the correction data). Each divided picture element can be controlled in accordance with the correction data. In addition, the number of source bus lines s can be reduced and the cost can be reduced as compared with the case where the source bus lines s are provided for each divided picture element (divided subpixel 22).

  The liquid crystal display device 1c according to the fourth aspect of the present invention is the liquid crystal display device 1c according to the second aspect, wherein the drive unit (the gate driver 11, the source driver 12, and the liquid crystal controller 13) includes the gate driver 11 and the source driver 12. The (subpixel 21) is composed of two divided picture elements (divided subpixels 22), and the two divided picture elements (divided subpixels 22) constituting each picture element (subpixel 21) are common gate bus lines g. And the gate driver 11 sequentially selects the gate bus line g, and the source driver 12 selects the gate bus line g selected by the gate driver 11. For each divided picture element (divided subpixel 22) connected to the line via the source bus line s Serial is configured to apply a potential corresponding to the gradation of the divided picture elements in the corrected image signal (divided sub-pixels 22).

  According to the above configuration, each divided picture element (divided subpixel 22) is individually set in the liquid crystal display panel 10 in which the picture element (subpixel 21) is composed of a plurality of divided picture elements (divided subpixel 22). Can be driven. Therefore, the same potential is applied to each divided picture element (divided subpixel 22) during measurement to generate correction data, and during normal display (when the input video signal is corrected and displayed according to the correction data). Each divided picture element (divided subpixel 22) can be controlled in accordance with the correction data.

  Further, by connecting two divided picture elements (divided subpixels 22) constituting the same picture element (subpixel 21) to a common gate bus line g, these divided picture elements (divided subpixels 22) are different. The number of gate bus lines g can be reduced as compared with the case of connecting to the gate bus lines g. Thereby, since the writing time of the liquid crystal with respect to each divided picture element (subpixel 21) can be lengthened, the size of the switching element provided in each divided picture element (divided subpixel 22) can be reduced. That is, when the writing time is short, it is necessary to flow a large amount of current when the switching element is turned on in order to complete the charging of the auxiliary capacitor within the writing time, and it is necessary to increase the size of the switching element. By increasing the writing time, the size of the switching element can be reduced. In addition, it is possible to take measures to suppress display unevenness such as thickening the wiring by using the extra space generated by reducing the size of the switching element. Alternatively, the aperture ratio of the liquid crystal display panel 10 can be improved by reducing the size of the switching element.

  In the liquid crystal display device 1d according to the fifth aspect of the present invention, in the third or fourth aspect, the source driver 12 provides the output voltage setting information for the source bus line s corresponding to a plurality of gradation values in the video signal as 2 Two sets of the setting information for the two divided picture elements (divided subpixels 22) constituting the picture element (subpixel 21) are provided with reference potential storage units (nonvolatile memories BANK_A and BANK_B) stored in pairs. The output voltage set using different sets of setting information is output.

  According to the above configuration, the gradation of each divided picture element (divided subpixel 22) can be easily set to a bright divided picture element and a dark divided picture element.

  The liquid crystal display device 1d according to aspect 6 of the present invention is the liquid crystal display device 1d according to aspect 5, in which the reference potential storage unit (nonvolatile memories BANK_A and BANK_B) receives the two sets of setting information for each source bus line s or a plurality of source buses. The source driver 12 stores the output voltage for each divided picture element (divided subpixel 22) and the source to which the divided picture element (divided subpixel 22) is connected. The setting is made using the setting information corresponding to the bus line s.

  According to the above configuration, the output voltage for each divided picture element (divided subpixel 22) can be adjusted for each source bus line s or each source bus line group.

  The liquid crystal display device 1e according to the seventh aspect of the present invention is the liquid crystal display device 1e according to the second aspect, wherein the drive unit (gate driver 11, source driver 12, liquid crystal controller 13) includes the gate driver 11 and the source driver 12, The (subpixel 21) is composed of two divided picture elements (divided subpixels 22), and the two divided picture elements (divided subpixels 22) constituting each picture element (subpixel 21) are common gate bus lines g. Are connected to a common source bus line s, the gate driver 11 sequentially selects the gate bus line g, and the source driver 12 selects the gate bus line selected by the gate driver 11. For each divided picture element (divided subpixel 22) connected to g via the source bus line s A potential corresponding to the gradation of the divided picture element (divided subpixel 22) in the corrected video signal is applied, and each picture element (subpixel 21) has a pixel electrode 34 and a gate terminal 51g as a gate bus line. The switching element (TFT 51) is connected to g, the source terminal 51s is connected to the source bus line s, and the drain terminal 51d is connected to the pixel electrode 34. The pixel electrode 34 is opposed to the pixel electrode 34 via the liquid crystal layer 33. And the auxiliary capacitor electrode (auxiliary capacitor line CS) capacitively coupled to the pixel electrode 34. The auxiliary capacitor electrode (auxiliary capacitor line CS) constitutes a picture element (subpixel 21). Two divided picture elements (divided subpixels 22) are provided individually, and different potentials are applied to the two divided picture elements (divided subpixels 22). It is configured to be.

  According to the above configuration, the voltage applied to the two divided picture elements (divided subpixels 22) constituting the picture element (subpixel 21) is controlled by controlling the potential of each auxiliary capacitance electrode (auxiliary capacitance line CS). Can be different. Thus, each divided picture element (divided subpixel 22) can be connected to the common gate bus line g and to the common source bus line s, so that the gate bus line g and the source bus line s can be connected to each other. The number can be reduced. Therefore, the configuration of the gate driver 11 and the source driver 12 can be simplified and the cost can be reduced. Further, when applying the same potential to each divided picture element (divided subpixel 22) in order to generate correction data, it is only necessary to connect each auxiliary capacitance electrode to a common power source (auxiliary capacitance line CS). A circuit for applying a potential for use can be realized at low cost.

  The liquid crystal display device (1b to 1e) according to aspect 8 of the present invention is the liquid crystal display device (1b to 1e) according to any one of aspects 1 to 7, wherein the gray level of the picture element (subpixel 21) in the input video signal and the picture element (subpixel 21) A division setting storage unit (division LUT 17) that stores division setting information that associates a combination of gradations of two divided picture elements (division subpixels 22) that constitutes the input video signal according to the division setting information. A pixel division unit (subpixel division unit 16) that generates a divided video signal obtained by dividing each of the pixel elements (subpixels 21) into a plurality of divided pixel units (divided subpixels 22). Correction data set for each gradation of the divided video signal and for each divided picture element (divided sub-pixel 22) is stored, and the correction calculation unit 14 uses the divided video signal as the correction data. Then, a corrected video signal is generated for each divided picture element (divided subpixel 22) by correction, and the number of gradations used in each divided picture element (divided subpixel 22) of the divided video signal is input. The configuration is smaller than the number of gradations used in each picture element (subpixel 21) of the video signal.

  According to the above configuration, since it is not necessary to store correction data in the storage unit 15 for gradations that are not used in any divided picture element (divided subpixel 22), correction to be stored in the storage unit 15 is not necessary. The data size of data can be reduced.

  In the liquid crystal display devices (1a to 1e) according to the ninth aspect of the present invention, in any one of the first to eighth aspects, the storage unit 15 viewed the liquid crystal display panel 10 as the correction data from different viewing angle directions. A plurality of first correction data generated so as to correct the display unevenness that is sometimes visible is stored, and the correction calculation unit 14 generates a second correction generated by combining the plurality of first correction data. An input video signal is corrected based on data, and the corrected video signal is generated.

  According to the above configuration, display unevenness can be appropriately corrected regardless of the viewing angle direction.

  The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope shown in the claims. That is, embodiments obtained by combining technical means appropriately modified within the scope of the claims are also included in the technical scope of the present invention.

  The present invention can be applied to a liquid crystal display device having a liquid crystal display panel provided with a plurality of picture elements composed of a plurality of divided picture elements.

1a to 1e Liquid crystal display device 10 Liquid crystal display panel 11 Gate driver (drive unit)
12, 12a to 12f Source driver (drive unit)
13 LCD controller (drive unit)
14 Correction calculation unit 15 Storage unit 16 Sub-pixel division unit 17 Division LUT
18 Pseudo gradation generation part 19 Sub pixel rearrangement part 20 Pixel 21, 21R, 21G, 21B Sub pixel (picture element)
22, 22a, 22b, 22Ra, 2Rb, 22Ga, 22Gb, 22Ba, 22Bb Divisional sub-pixel (division picture element)
31 TFT glass substrate 32 CF glass substrate 33 Liquid crystal layer 34 Pixel electrode 35 Counter electrode 36 Color filter 37 TFT side polarizing plate 38 CF side polarizing plate 39 Optical sheet group 40 Backlight 51 TFT (switching element)
51d Drain terminal 51g Gate terminal 51s Source terminal 52 Counter electrode wiring 61, 62 Structure 71 Correction data expansion unit 81, 81b Gradation DAC
82 Regulator 83 CS power supply circuit 84 VCOM power supply circuit 85 Switching circuit 91 Comparator 92 Serial / parallel converter 93 Shift register 94 Sampling memory 95 Hold memory 96 Level shifter 97 Reference voltage generation circuit 98 DA converter 99 Output circuit 101 Non-volatile memory 102 DAC
103 Amplifier 104 Power supply circuit 105a Switch BANK_A, BANK_B Non-volatile memory (reference potential storage unit)
CS Auxiliary capacitance wiring (auxiliary capacitance electrode)
g Gate bus line s Source bus line

Claims (9)

A liquid crystal display panel provided with a plurality of picture elements composed of a plurality of divided picture elements;
A storage unit for storing correction data set for each gradation of the input video signal and for each of the divided picture elements;
A correction calculation unit that corrects an input video signal based on the correction data and generates a corrected video signal for each of the divided picture elements;
A drive unit that drives each of the divided picture elements according to the corrected video signal,
The correction data can suppress display unevenness of the liquid crystal display panel even when the viewing angle directions are different based on the result of measuring the display characteristics of the liquid crystal display panel displaying the measurement image from a plurality of viewing angle directions. A liquid crystal display device characterized by being generated correction data.   The correction data is correction data set for each divided picture element based on a result of measuring the display characteristics of the liquid crystal display panel when the same potential is applied to each of the divided picture elements from a plurality of viewing angle directions. The liquid crystal display device according to claim 1. The driving unit includes a gate driver and a source driver,
The picture element consists of two divided picture elements,
Two divided picture elements constituting each picture element are connected to different gate bus lines and connected to a common source bus line,
The gate driver sequentially selects the gate bus lines,
The source driver responds to the gradation of the divided picture element in the corrected video signal through the source bus line for each divided picture element connected to the gate bus line selected by the gate driver. The liquid crystal display device according to claim 2, wherein a potential is applied. The driving unit includes a gate driver and a source driver,
The picture element consists of two divided picture elements,
Two divided picture elements constituting each picture element are connected to a common gate bus line and connected to different source bus lines,
The gate driver sequentially selects the gate bus lines,
The source driver responds to the gradation of the divided picture element in the corrected video signal through the source bus line for each divided picture element connected to the gate bus line selected by the gate driver. The liquid crystal display device according to claim 2, wherein a potential is applied. The source driver is
A reference potential storage section storing two sets of output voltage setting information for the source bus line corresponding to a plurality of gradation values in a video signal;
5. The liquid crystal according to claim 3, wherein an output voltage for two divided picture elements constituting the picture element is set by using different sets of setting information among the two sets of setting information. Display device. The reference potential storage unit stores the two sets of setting information for each source bus line or for each source bus line group including a plurality of source bus lines,
6. The liquid crystal display device according to claim 5, wherein the source driver sets an output voltage for each divided picture element using the setting information corresponding to a source bus line to which the divided picture element is connected. The driving unit includes a gate driver and a source driver,
The picture element consists of two divided picture elements,
The two divided picture elements constituting each picture element are connected to a common gate bus line and connected to a common source bus line,
The gate driver sequentially selects the gate bus lines,
The source driver responds to the gradation of the divided picture element in the corrected video signal through the source bus line for each divided picture element connected to the gate bus line selected by the gate driver. Applying a potential,
Each picture element is
A pixel electrode;
A switching element having a gate terminal connected to the gate bus line, a source terminal connected to the source bus line, and a drain terminal connected to the pixel electrode;
A counter electrode disposed opposite to the pixel electrode via a liquid crystal layer;
An auxiliary capacitance electrode capacitively coupled to the pixel electrode,
3. The liquid crystal according to claim 2, wherein the auxiliary capacitance electrode is individually provided for each of the two divided picture elements constituting the picture element, and a different potential is applied to each of the two divided picture elements. Display device. A division setting storage unit that stores division setting information in which gradations of picture elements in an input video signal and combinations of gradations of two divided picture elements constituting the picture element are associated;
A pixel division unit that generates a divided video signal obtained by dividing each picture element in the input video signal into a plurality of divided picture elements according to the division setting information;
The storage unit stores correction data set for each gradation of the divided video signal and for each divided picture element,
The correction calculation unit corrects the divided video signal based on the correction data to generate a corrected video signal for each divided picture element,
The number of gradations used in each divided picture element of the divided video signal is smaller than the number of gradations used in each picture element of the input video signal. A liquid crystal display device according to 1. The storage unit stores, as the correction data, a plurality of first correction data generated so as to correct display unevenness visually recognized when the liquid crystal display panel is viewed from different viewing angle directions,
The correction calculation unit corrects an input video signal based on second correction data generated by combining a plurality of the first correction data, and generates the corrected video signal. The liquid crystal display device according to any one of 8.

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