The present invention relates to a liquid crystal display apparatus.
Liquid crystal panels of liquid crystal display apparatuses for mobile use such as smart phones are required to have low power consumption capable of withstanding long-time use. For point of sale (POS) use that is used outside, the liquid crystal panels are required to have enhanced brightness for improving visibility.
To achieve the characteristics (low power consumption and enhanced brightness), liquid crystal display panels in which four pixels as one picture element are on display instead of three pixels as one picture element on display have been developed and, in fact, have been commercially available. The three pixels (hereinafter also referred to as RGB pixels) are red (R), green (G), and blue (B), which are the conventional three primary colors. The four pixels (hereinafter also referred to as RGBW pixels) are white (W) in addition to the three primary colors.
For display by the RGB pixels, a chromaticity (color temperature) of a white display is formed by additive color mixture of light that has passed through a color filter corresponding to each of the pixels of red, green, and blue. Meanwhile, for display by the RGBW pixels, a chromaticity of a white display is formed by additive color mixture of light that has passed through a color filter corresponding to each of the pixels of red, green, and blue and light that has passed through a translucent filter (in other words, transmittance has no wavelength dependence) corresponding to the white pixel.
As described above, the chromaticity of the white display formed by the RGB pixels does not typically coincide with the chromaticity of the white display formed by the RGBW pixels. Thus, if the RGB pixels are changed to the RGBW pixels for improving the transmittance, the chromaticity of the white display by the RGBW pixels is different from the chromaticity of the white display by the RGB pixels (shift in the chromaticity of the white display).
To obtain a desired chromaticity of the white display by the RGBW pixels, a filter corresponding to the white pixel has conventionally been used and is made of a special material having different light absorption coefficients between a long wavelength side and a short wavelength side in a visible region (for example, see Japanese Patent Application Laid-Open No. 11-295717 (1999)).
Moreover, in a liquid crystal display apparatus that has the RGBW pixels as the one picture element (basic unit) and is driven in a fringe field switch (FFS) mode, slits corresponding to the white pixel are disposed symmetrically with respect to slits corresponding to the red pixel, the green pixel and the blue pixel (for example, see Japanese Patent Application Laid-Open No. 2005-309052).
In Japanese Patent Application Laid-Open No. 11-295717 (1999), the special material forming the filter needs development, thereby requiring a cost of the development.
Japanese Patent Application Laid-Open No. 2005-309052 discloses a configuration for preventing a color shift in a range of viewing angles, namely, a tint from an oblique view. The configuration does not achieve the effect of matching the chromaticity of the white display formed by the RGB pixels with the chromaticity of the white display formed by the RGBW pixels.
In this manner, the change from the RGB pixels to the RGBW pixels could not have resolved the shift in the chromaticity of the white display.
It is an object of the present invention to provide a liquid crystal display apparatus capable of resolving a shift in a chromaticity of a white display to obtain a desired chromaticity of the white display by RGBW pixels.
A liquid crystal display apparatus that controls liquid crystals with a pixel structure having a red pixel, a green pixel, a blue pixel, and a white pixel as a basic unit. Voltage-transmittance characteristics of the liquid crystals corresponding to the white pixel are different from voltage-transmittance characteristics of the liquid crystals corresponding to each of the red pixel, the green pixel, and the blue pixel.
The present invention is the liquid crystal display apparatus that controls the liquid crystals with the pixel structure having the red pixel, the green pixel, the blue pixel, and the white pixel as the basic unit. The voltage-transmittance characteristics of the liquid crystals corresponding to the white pixel are different from the voltage-transmittance characteristics of the liquid crystals corresponding to each of the red pixel, the green pixel, and the blue pixel. Thus, the liquid crystal display apparatus can resolve the shift in the chromaticity of the white display to obtain the desired chromaticity of the white display.
These and other objects, features, aspects and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings.
Preferred embodiments of the present invention will be described below with reference to the drawings.
As shown in
The red slit electrode 1 is provided correspondingly to a red pixel and has a plurality of slits 2 so as to have a line width WR and a space SR. In other words, each of the slits 2 has a length in a short-side direction that corresponds to the space SR, and the slits 2 have an interval formed therebetween that corresponds to the line width WR. In this manner, the red slit electrode 1 has the plurality of slits 2 that generate the fringe electric field upon voltage application.
Each of the slits 2 is formed to have an angle of θR between a long-side direction of each of the slits 2 and an alignment axis 5 of the liquid crystals (not shown).
The white slit electrode 3 is provided correspondingly to a white pixel and has a plurality of slits 4 so as to have a line width WW and a space SW. In other words, each of the slits 4 has a length in a short-side direction that corresponds to the space SW, and the slits 4 have an interval formed therebetween that corresponds to the line width WW. In this manner, the white slit electrode 3 has the plurality of slits 4 that generate the fringe electric field upon voltage application.
Each of the slits 4 is formed to have an angle of θW between a long-side direction of each of the slits 4 and an alignment axis 5 of the liquid crystals (not shown). In the configuration described above, the angle θR of the slit 2 formed in the red slit electrode 1 is different from the angle θW of the slit 4 formed in the white slit electrode 3.
A line width WR/space SR ratio (ratio of an arrangement space of each slit to a length of each slit in a short-side direction) in the red slit electrode 1 is different from a line width WW/space SW ratio in the white slit electrode 3.
In addition, a green slit electrode (not shown) provided correspondingly to a green pixel and a blue slit electrode (not shown) provided correspondingly to a blue pixel are also provided on the TFT substrate similarly to the red slit electrode 1 shown in
Hereinafter, the red slit electrode 1, the white slit electrode 3, and the like are collectively and simply referred to as a slit electrode. The angle θR, the angle θW, and the like are collectively and simply referred to as an angle θ. The same holds true for the line width WR, the line width WW, the space SR, and the space SW, and the like.
The liquid crystal display apparatus driven in the FFS mode has two broad types of configurations of the pixels. In other words, the one type includes an pixel electrode that is connected to a TFT and disposed as an upper layer and a common electrode that is supplied with a common potential and disposed as a lower layer, and the other type includes the common electrode disposed as the upper layer and the pixel electrode disposed as the lower layer. In the first preferred embodiment, any of the types described above may include an electrode disposed as the upper layer having a configuration similar to that of the slit electrode shown in
In the liquid crystal display apparatus driven in the FFS mode, to prevent a color shift in a range of viewing angles, the slit electrodes having a symmetric shape are conceivably disposed with respect to a symmetric axis that is a boundary dividing each pixel horizontally into two at the center. Also in this case, each of the slit electrodes disposed vertically may have a configuration similar to that of the slit electrode shown in
In
In the FFS mode, the voltage-transmittance characteristics (V-T characteristics) of the liquid crystals vary according to the angle θ and the line width W/space S ratio of the slit electrode.
As seen from
In
The voltage-transmittance characteristics are also affected by the line width W/space S ratio of the slit electrode.
As seen from
In
As shown in
The chromaticity varies according to the relative transmittance as described above, so that the chromaticity can be controlled by changing the voltage-transmittance characteristics while the applied voltage is in the constant state.
Specifically, the change in the angle θ and the line width W/space S ratio of the slit electrode can change the voltage-transmittance characteristics as described above. Therefore, the voltage-transmittance characteristics can be controlled by the single white pixel with the change in the angle θ and the line width W/space S ratio of the slit electrode corresponding to the single white pixel, allowing for the change in the chromaticity of the light that passes through the liquid crystals corresponding to the white pixel. In other words, the voltage-transmittance characteristics of the liquid crystals corresponding to the white pixel are different from the voltage-transmittance characteristics of the liquid crystals corresponding to each of the red pixel, the green pixel, and the blue pixel.
In addition,
A description is given next of a method of matching (coinciding) the chromaticity of the white display formed by the RGB pixels with the chromaticity of the white display formed by the white pixel in the case where the RGBW pixels are assumed to be the one picture element (basic unit).
As shown in
In the case above, the white slit electrode 3 has the greater angle θW or has the greater space SW of the line width WW/space SW ratio to shift the voltage-transmittance characteristics to the high voltage side, whereby the chromaticity value of the white display formed by the white pixel can be matched (coincided) with the chromaticity value of the white display formed by the RGB pixels (see
Thus, the first preferred embodiment can resolve the shift in the chromaticity of the white display to obtain the desired chromaticity of the white display by the RGBW pixels.
As shown in
A color filter 11 and an overcoat film 12 are laminated on the CF substrate 10.
The color filter 11 has a position corresponding to each of a red pixel, a green pixel, and a blue pixel colored by a corresponding color (color resist film).
The overcoat film 12 is transparent and is formed on the color filter 11 (on the liquid crystal layer 13 side).
The color filter 11 and the overcoat film 12 that are formed in the position corresponding to the white pixel are transparent and may use the same transparent resist film.
As shown in
In
In the liquid crystal display apparatus driven in the FFS mode, it is widely known that the retardation Δn·d (d and Δn represent the thickness and a refractive index anisotropy of the liquid crystal layer 13, respectively) of the liquid crystal cells changes a spectrum of light that passes through the liquid crystals.
As shown in
A description is given next of a method of matching (coinciding) the chromaticity of the white display formed by the RGB pixels with the chromaticity of the white display formed by the white pixel in a case where the RGBW pixels are assumed to be one picture element (basic unit).
As shown in
To change the cell gap (cell gap 15 in
Thus, the second preferred embodiment similar to the first preferred embodiment can resolve the shift in the chromaticity of the white display to obtain the desired chromaticity of the white display by the RGBW pixels.
The first preferred embodiment may be applied to the second preferred embodiment. In this case, the range of adjustments to the chromaticity of the white display of the white pixel expands, allowing for fine adjustments as well.
The black matrix 17 (light shielding layer) is disposed on a CF substrate on a display surface side with respect to liquid crystals.
As shown in
An area of the opening 21 corresponding to the white pixel is different from an area of each of the openings 18 to 20 corresponding to the red pixel, the green pixel, and the blue pixel.
An intensity of the light that passes through the liquid crystals (such as the liquid crystal layer 13 in
Thus, the third preferred embodiment similar to the first preferred embodiment can resolve the shift in the chromaticity of the white display to obtain the desired chromaticity of the white display by the RGBW pixels.
The first preferred embodiment and the second preferred embodiment may be applied to the third preferred embodiment. In this case, the range of adjustments to the chromaticity of the white display of the white pixel expands, allowing for fine adjustments as well.
In addition, according to the present invention, the above preferred embodiments can be arbitrarily combined, or each preferred embodiment can be appropriately varied or omitted within the scope of the invention.
While the invention has been shown and described in detail, the foregoing description is in all aspects illustrative and not restrictive. It is therefore understood that numerous modifications and variations can be devised without departing from the scope of the invention.
Number | Date | Country | Kind |
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2014-024992 | Feb 2014 | JP | national |
Number | Date | Country | |
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Parent | 14601713 | Jan 2015 | US |
Child | 15703784 | US |