JP5526490B2 - Driving method of display element - Google Patents

Description

  The present invention relates to a method for driving a display element in which one picture element is composed of pixels of four colors of red, green, blue, and white.

  2. Description of the Related Art Conventionally, as a display element for displaying a color image, a display element in which one picture element is configured by four color pixels of red, green, blue, and white has been proposed in order to brighten a screen (Patent Document 1). reference).

The display element in which one picture element is constituted by the pixels of the four colors is based on the supplied gradation data of the three colors of red, green, and blue, and has the minimum value among the gradation data of these three colors. A bias value is determined by calculation from the gradation data , and the value is used as driving gradation data for white pixels. The driving gradation data for the white pixels is respectively obtained from the input gradation data of three colors of red, green, and blue. Is obtained by subtracting the gradation values of the three colors to obtain driving gradation data for each of the three colors of red, green, and blue, and data for four colors of red, green, blue, and white corresponding to these driving gradation data, respectively. It is driven by a method of supplying signals to pixels of four colors of red, green, blue, and white, respectively (see Patent Document 2).

  However, in the above-described conventional driving method, when the gradation values of the supplied three color data of red, green, and blue are different from each other, that is, the three color gradation data of red, green, and blue are red, When the data is an intermediate color in which three colors of green and blue are mixed at different ratios, a color shift occurs in the display color of the display element, and the supplied three gradations of red, green and blue A color image with good color reproducibility corresponding to the data cannot be displayed.

  The present invention provides color reproduction corresponding to gradation data of three colors of red, green and blue supplied to a liquid crystal display element in which one picture element is constituted by pixels of four colors of red, green, blue and white. An object of the present invention is to provide a driving method capable of displaying a color image with good characteristics.

In order to solve the above problems, one aspect of the display element driving method of the present invention is:
A plurality of pixels of four colors of red, green, blue, and white are arranged in a predetermined order, and one picture element is formed by four pixels of each color of red, green, blue, and white adjacent to each other. In a method of driving a display element to be configured based on supplied gradation data of three colors of red, green, and blue,
Red for defining the display color of one picture element, green, three-color gradation data D _R of _blue, D _G, for each value of D _B,
R ′ _R = R _R {1 + tR _min (L _maxR + L _maxG + L _maxB ) / (R _R L _maxR + R _G L _maxG + R _B L _maxB )} − R ′ _W L _maxW / (L _maxR + L _maxG + L _maxB )
_{R 'G = R G {1} + tR min (L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} - R' W L maxW / (L maxR + L maxG + L maxB)
_{R 'B = R B {1} + tR min (L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} - R' W L maxW / (L maxR + L maxG + L maxB)
However, R ′ _R , R ′ _G , R ′ _B , and R ′ _W are input gradation values D ′ _R , D ′ _G , D ′ _B , and D ′ to pixels of red, green, blue, and white colors, respectively. The luminance when the voltage corresponding to _W is applied is the display luminance L ′ _R , L ′ _G , L ′ _B , L ′ _W , and the maximum gradation value of each of the four colors of red, green, blue and white pixels. _Is the maximum gradation luminance L _maxR , L _maxG , L _maxB , L _maxW, and the luminance when a voltage corresponding to the input gradation values D ′ _R , D ′ _G , D ′ _B , D ′ _W is applied. The display luminance ratios R ′ _R = L ′ _R / L _maxR , R ′ _G = L ′ _G / L _{max G} , R ′ _B = L ′ _B / L _{max B} , R ′ _W = L ′ _W / L _{max W} red, green, blue, and gradation data D to each color of a pixel of white _R, D _G, the gradation data luminance is a luminance when applying a voltage corresponding to the _{D B L R, L G,} L And _B, and the gray-scale data luminance _{L R, L G,} the gradation data luminance ratio _{L B R R = L R /} L maxR, R G = L G / L maxG, R B = L B / L maxB The gradation data luminance rate is R _R , R _G , R _B , the minimum value is R _min , t is greater than 0 , and L _maxW / (L _{max R} + L _maxG + L _maxB ) or less. It is an arbitrary value set in advance,
And, display brightness ratio R of the white pixel _'W red, green, blue, and the display brightness L of each color of the pixels of the white' _R, L _'G, L' _B, of the L _'W, these values pixels but made the color of pixels to be the smallest value, and second-color becomes a small value pixel, and but if they are arranged adjacent to each other on the front示画surface is the second smallest value the And a value that substantially matches the luminance rate of
The display luminance _{L 'R, L' G,} L 'B, L' and pixels, the colors of these values is the smallest value of _W, and the color of the pixel to be the second smallest value, but TABLE If they are not adjacent to each other on the display screen, the value is substantially matched with the luminance rate of the pixel having the smallest value, and red, green, blue, and white are set so as to satisfy the respective expressions. input tone value D _'R, D' supplied to the respective colors of the pixel _G, D _'B, D' calculates _W, these tone values _{D 'R, D' G,} D 'B, D' W of Supply four color data signals to red, green, blue and white pixels respectively ;
It is characterized by that.

In order to solve the above problems, one aspect of the display element driving method of the present invention is:
A plurality of pixels of four colors of red, green, blue, and white are arranged in a predetermined order, and one picture element is formed by four pixels of each color of red, green, blue, and white adjacent to each other. a display device which constitutes the supplied red, green, three-color gray-scale data D _R of _blue, D _G, red on the basis of D _B, respectively supply green, blue, and four-color pixels of white 4 In a method of driving by generating two input gradation values D ′ _R , D ′ _G , D ′ _B and D ′ _W and supplying them to each pixel,
The four color pixels of red, green, blue, and white have the input gradation value supplied to each pixel and the luminance obtained by applying a voltage according to the input gradation value. Formed to be proportional,
Red corresponding to the supplied gradation data, green, _R three color gradation data luminance of the pixels of the blue, respectively _{R = D R / D f,} R G = D G / D f, R B = D B / _{D f (D} f is the maximum value of gradation) expressed in, the gradation level data luminance factor _{R R,} R G, the minimum value of _{R B} and _{R min,}
When gray-scale data _{D R,} D G, is _{D B} all 0,
The four input gradation values D ′ _R , D ′ _G , D ′ _B and D ′ _W are all set to 0,
Grayscale data _{D R,} D G, when at least one of _{D B} other than 0,
The input tone value D′ _R is
_{D R {1 + tR min (} L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} - C'L maxW / (L maxR + L maxG + L maxB)
To an integer value,
The input tone value D′ _G is
D _G {1 + tR _min (L _maxR + L _maxG + L _maxB ) / (R _R L _maxR + R _G L _maxG + R _B L _maxB )} − C′L _maxW / (L _maxR + L _maxG + L _maxB )
To an integer value,
The input tone value D′ _B is
D _B {1 + tR _min (L _maxR + L _maxG + L _maxB ) / (R _R L _maxR + R _G L _maxG + R _B L _maxB )} − C′L _maxW / (L _maxR + L _maxG + L _maxB )
To an integer value,
The input tone value D′ _W is a value obtained by converting C ′ into an integer.
However , R ′ _R , R ′ _G , R ′ _B , and R ′ _W are input gradation values D ′ _R , D ′ _G , D ′ _B , and D ′ to pixels of red, green, blue , and white colors, respectively. The luminance when the voltage corresponding to _W is applied is the display luminance L ′ _R , L ′ _G , L ′ _B , L ′ _W , and the maximum gradation value of each pixel of each color of red, green, blue , and white The luminance ratio when the voltages corresponding to the input gradation values D ′ _R , D ′ _G , D ′ _B , and D ′ _W are applied with the maximum gradation luminances L _maxR , L _maxG , L _maxB , and L _maxW R ′ _R = L ′ _R / L _max R, R ′ _G = L ′ _G / L _{max G} , R ′ _B = L ′ _B / L _{max B} , R ′ _W = L ′ _W / L _{max W} , red , green, wherein the respective colors of the pixels of the blue gradation data _{D R,} D G, the gradation data luminance is a luminance when applying a voltage corresponding to the _{D B L R, L G,} L B And, a t greater than 0, and advance any of the values defined for _{L maxW / (L max R +} L maxG + L maxB) following ranges,
Where C ′ is
The first tone value coefficients D _fR , D _fG , D _fB are
_{D fR = D R {1 +} tR min (L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} (L maxR + L maxG + L maxB) / (2L maxR + L maxG + L maxB)
_{D fG = D G {1 +} tR min (L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} (L maxR + L maxG + L maxB) / (L maxR + 2L maxG + LmaxB)
_{D fB = D B {1 +} tR min (L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} (L maxR + L maxG + L maxB) / (L maxR + L maxG + 2L maxB)
And define
The second gradation value coefficients D _mR , D _mG , and D _{m B} are set to D _mR = D _R {1 + tR _min (L _maxR + L _maxG + L _maxB ) / (R _R L _maxR + R _G L _maxG + R _B L _maxB )}
D _mG = D _G {1 + tR _min (L _maxR + L _maxG + L _maxB ) / (R _R L _maxR + R _G L _maxG + R _B L _maxB )}
D _mB = D _B {1 + tR _min (L _maxR + L _maxG + L _maxB ) / (R _R L _maxR + R _G L _maxG + R _B L _maxB )}
And define
The smallest value among these second gradation value coefficients D _mR , D _mG and D _{m B} is D _{m min} , and the second gradation value coefficient D _mR , D _mG and D _{m B} is When the largest value is D _{m max} ,
First gradation value coefficient _{D fR, D fG,} of _{D fB,} the smallest value _{D fR} or _{D fB,} is the second smallest value is when _{D fG,}
If D _{m min} <D _fG ,
_{C '= D m min (L} maxR + L maxG + L maxB) / L maxW
If D _{m max} −D _f > D _fG ,
C ′ = (D _{m max} −D _f ) (L _maxR + L _maxG + L _maxB ) / L _{maxW
D mmin} <D _fG, and, D _{m max} -D _f> otherwise _{D fG,}
C ′ = D _fG (L _maxR + L _maxG + L _maxB ) / L _maxW
First gradation value coefficient _{D fR, D fG,} of _{D fB,} the smallest value _{D fR,} is the second smallest value is when _{D fB,}
If D _{m min} <D _fB ,
_{C '= D m min (L} maxR + L maxG + L maxB) / L maxW
If D _{m max} −D _f > D _fB ,
C ′ = (D _{m max} −D _f ) (L _maxR + L _maxG + L _maxB ) / L _{maxW
D m min} <D _fB, and, D _{m max} -D _f> otherwise _{D fB,}
C ′ = D _fB (L _maxR + L _maxG + L _maxB ) / L _maxW
First gradation value coefficient _{D fR, D fG,} of _{D fB,} the smallest value _{D fB,} is the second smallest value is when _{D fR,}
If D _{m min} <D _fR ,
_{C '= D m min (L} maxR + L maxG + L maxB) / L maxW
If D _{m max} −D _f > D _{f R} ,
C ′ = (D _{m max} −D _f ) (L _maxR + L _maxG + L _maxB ) / L _{maxW
D m min} <D _fR, and, D _{m max} -D _f> otherwise _{D fR,}
C ′ = D _fR (L _maxR + L _maxG + L _maxB ) / L _maxW
First gradation value coefficient _{D fR, D fG,} when one of the _{D fB,} the smallest value of _{D fG,}
If D _{m min} <D _fG ,
_{C '= D m min (L} maxR + L maxG + L maxB) / L maxW
If D _{m max} −D _f > D _fG ,
C ′ = (D _{m max} −D _f ) (L _maxR + L _maxG + L _maxB ) / L _{maxW
D m min} <D _fG, and, D _{m max} -D _f> otherwise _{D fG,}
C ′ = D _fG (L _maxR + L _maxG + L _maxB ) / L _maxW
And the calculated input gradation values D ′ _R , D ′ _G , D ′ _B , and D ′ _W are used as the four color data signals of red, green, blue, and white, respectively. Supply to each of the pixels ,
It is characterized by that.

  According to the driving method of the present invention, the gradation data of the three colors red, green, and blue supplied to the liquid crystal display element in which one picture element is constituted by the pixels of four colors of red, green, blue, and white. A color image with good color reproducibility corresponding to can be displayed.

FIG. 1 is a configuration diagram of a display device. This display device has a plurality of pixels 13R, 13G, 13B, and 13W (see FIG. 2) of four colors of red, green, blue, and white in a predetermined order. A plurality of arranged red, green, blue and white pixels constitute one picture element, for example, a liquid crystal display element 1 and three colors of red, green and blue supplied from the outside. based on the gradation data of red, green, and generates a 4-color gray-scale data of blue and white, and drive means 15 for driving the liquid crystal display device 1, and is composed of.

FIG. 2 is a cross-sectional view of a part of the liquid crystal display element 1. The liquid crystal display element 1 includes a pair of transparent substrates 2 and 3 that are arranged to face each other with a predetermined gap therebetween, and between these substrates 2 and 3. On the inner surface of one of the pair of substrates 2 and 3, for example, the opposite side to the observation side (upper side in the figure), and in the row direction (horizontal direction of the screen) and the column A plurality of transparent pixel electrodes 5 arranged in a matrix in the direction (vertical direction of the screen) and the inner surface of the other substrate, that is, the substrate 3 on the observation side, in the arrangement region of the plurality of pixel electrodes 5 a single film-like transparent counter electrode 6 formed in correspondence, and a pair of polarizing plates 12 and 13 respectively disposed on an outer surface of the pair of substrates 2 and 3, is made of.

The liquid crystal display element 1 is an active matrix liquid crystal display element using TFTs (thin film transistors) as active elements, and although not shown in FIG. 1, the liquid crystal display element 1 is formed on the inner surface of the opposite substrate 2 on which the plurality of pixel electrodes 5 are formed. , A plurality of TFTs arranged corresponding to the plurality of pixel electrodes 5, respectively, connected to these pixel electrodes 5, a plurality of scanning lines for supplying gate signals to the TFTs in each row, a plurality of data lines for supplying data signals to the TFT, is provided.

The liquid crystal display element 1 displays an image by controlling the transmittance of light emitted from a surface light source (not shown) disposed on the side opposite to the observation side. The alignment state of the liquid crystal molecules in the liquid crystal layer 4 is changed by supplying the data signal, that is, by applying a voltage corresponding to the data signal between the electrodes 5 and 6 depending on the region facing the counter electrode 6. a plurality of pixels 13R for controlling the transmittance of light, 13G, 13B, 13W are formed.

  Of the plurality of pixels 13R, 13G, 13B, and 13W, 1/4 of the pixels 13R are red pixels including the red color filter 7R, and the other 1/4 of the pixels 13G are green color filters 7G. A green pixel having a color filter, and another 1/4 pixel 13B are a blue pixel having a blue color filter 7B, and the remaining 1/4 pixel 13W is a white pixel having no color filter. The plurality of pixels 13R, 13G, 13B, and 13W of the colors red, green, blue, and white are alternately arranged in a matrix.

  The color filters 7R, 7G, and 7B are formed on one of the pair of substrates 2 and 3, for example, on the inner surface of the observation side substrate 3, and further on the inner surface of the observation side substrate 3, the white pixel 13W. The colorless transparent film 8 for adjusting the thickness of the liquid crystal layer of the white pixel 13W to the same level as the thickness of the liquid crystal layers of the three colors red, green, and blue 13R, 13G, and 13B is provided. Is formed.

  The counter electrode 6 is formed on the color filters 7R, 7G, and 7B and the colorless transparent film 8, and the inner surfaces of the pair of substrates 2 and 3 respectively include the plurality of pixels. Alignment films 9 and 10 are provided so as to cover the electrode 5 and the counter electrode 6.

  The pair of substrates 2 and 3 are arranged to face each other with a predetermined gap therebetween, and a frame-shaped sealing material (a frame-shaped sealing material surrounding the screen region in which the plurality of pixels 13R, 13G, 13B, and 13W are arranged in a matrix form) The liquid crystal layer 4 is sealed in a region surrounded by the sealing material between the substrates 2 and 3.

  The liquid crystal display element 1 includes a TN or STN type in which the liquid crystal molecules of the liquid crystal layer 4 are twist-aligned, a vertical alignment type in which the liquid crystal molecules are aligned substantially perpendicular to the surfaces of the substrates 2 and 3, and liquid crystal molecules. Either a horizontal alignment type that is aligned substantially parallel to the surfaces of the substrates 2 and 3 without twisting, a bend alignment type that bends liquid crystal molecules, or a ferroelectric or antiferroelectric liquid crystal display device. The pair of polarizing plates 11 and 12 is set so that the direction of the respective transmission axes is black when no voltage is applied between the electrodes 5 and 6 of the pixels 13R, 13G, 13B, and 13W. Are arranged.

  The liquid crystal display element 1 shown in FIG. 1 changes the alignment state of liquid crystal molecules by generating an electric field between the electrodes 5 and 6 provided on the inner surfaces of the pair of substrates 2 and 3, respectively. For example, comb-like first and second electrodes for forming a plurality of pixels are provided on the inner surface of one of the pair of substrates, and a horizontal electric field (direction along the substrate surface) is provided between these electrodes. A lateral electric field control type in which the alignment state of the liquid crystal molecules is changed by generating an electric field).

  The liquid crystal display element 1 includes one picture element 14 composed of four pixels 13R, 13G, 13B, and 13W, each of which is adjacent to each other, red, green, blue, and white, in a matrix form. A color image is displayed by the plurality of arranged picture elements 14.

  The liquid crystal display element 1 includes four pixels 13R, 13G, 13B, and 13W of four colors, red, green, blue, and white. Therefore, the liquid crystal display element 1 does not include a white pixel, and includes red, green, The screen can be brightened compared to the liquid crystal display element of three color pixels in which one picture element is constituted by three blue color pixels.

Next, a driving method of the liquid crystal display element 1 will be described. The liquid crystal display element 1 is divided into three levels of red, green, and blue of the video signal supplied from the outside by the driving means 15 shown in FIG. scale data (red, green, data specifying the three colors of the gradation of blue) D _{R, D G,} based on D _B, red for each of the plurality of picture element 14, green, blue, and four colors of white Drive gradation data D ′ _R , D ′ _G , D ′ _B , and D ′ _W for red, green, blue, and white for driving the pixels 13R, 13G, 13B, and 13W are generated. The four color data signals respectively corresponding to the drive gradation data D ′ _R , D ′ _G , D ′ _B , and D ′ _W are converted into four colors of red, green, blue, and white of the plurality of picture elements 14. Driving is performed by supplying the pixels 13R, 13G, 13B, and 13W, respectively.

The driving unit 15 supplies a gate signal for sequentially turning on the TFT to a plurality of scanning lines of the liquid crystal display element 1 and a data signal to the plurality of data lines of the liquid crystal display element 1. and supplies the data driving circuit 17, the red of the video signal, a green, three-color gray-scale data D _R of _blue, D _G, red for each of the plurality of picture elements 14 of the liquid crystal display device 1 based on D _B, An operation unit 18 for generating drive gradation data D ′ _R , D ′ _G , D ′ _B , D ′ _W of four colors of green, blue, and white, a voltage corresponding to the gate signal, and the red, A power supply unit 19 for generating voltages having a plurality of values corresponding to the number of gradations of drive gradation data D ′ _R , D ′ _G , D ′ _B , and D ′ _W for four colors of green, blue, and white; a controller 20 for controlling the scan driver 16 and the data driving circuit 17 and the arithmetic unit 18, Tona To have.

Said video signal includes a synchronization signal corresponding to an image to be displayed, the red for defining the display color of each of the plurality of picture elements 14, green, three-color gray-scale data D _R of _blue, D _G, D _B When a signal containing, inputted to the controller 20.

The controller 20 separates the synchronization signal and the like from the video signal and supplies them to the scanning drive circuit 16 and the data drive circuit 17, and the gradation data D _R , red, green and blue of the three colors. D _G, the _{D B} is supplied to the arithmetic unit 18, controls the operation of these circuits.

The arithmetic unit 18, the red input from the controller 20, green, three-color gray-scale data D _R of _blue, D _G, based on D _B, by calculation in accordance with a predetermined algorithm, the liquid crystal The drive gradation data D ′ _R , D ′ _G , D ′ _B , and D ′ _W of red, green, blue, and white for each of the plurality of picture elements 14 of the display element 1 are generated, and these drive floors are generated. The tone data D ′ _R , D ′ _G , D ′ _B , and D ′ _W are supplied to the data driving circuit 17.

  The scan driving circuit 16 sequentially supplies a gate signal having a voltage value generated by the power supply unit 19 to a plurality of scan lines of the liquid crystal display element 1 in accordance with a synchronization signal from the controller 20.

The data driving circuit 17 has voltages corresponding to the driving gradation data D ′ _R , D ′ _G , D ′ _B , and D ′ _W for the four colors of red, green, blue, and white from the arithmetic unit 18, respectively. Is selected from the power supply unit 19 and the four color data signals of red, green, blue, and white having these voltage values are supplied to the plurality of data lines of the liquid crystal display element 1 in correspondence with the synchronization signal.

That is, the driving unit 15 sequentially selects a plurality of pixel rows of the liquid crystal display element 1 by supplying gate signals to the plurality of scanning lines, and pixels of the pixels 13R, 13G, 13B, and 13W in the selected row. The drive gradation data D ′ _R , D ′ _G , D ′ _B , D ′ _W for four colors of red, green, blue, and white for each of the plurality of picture elements generated in the calculation unit 18 is applied to the electrode 5. The four color data signals respectively corresponding to the above are supplied through the plurality of signal lines and TFTs.

The driving method for each of the plurality of picture elements 14 of the liquid crystal display device 1, red for defining the display color of one picture element 14, green, three-color gray-scale data D _R of _blue, D _G red of the one picture element 14 corresponding respectively to the _{D B,} green, three-color pixels 13R blue, 13G, to the total value of the luminance of 13B, each pixel 13R, 13G, maximum brightness of the sum of 13B The four pixels 13R, 13G, and 13B of four colors of red, green, blue, and white of the one picture element 14 based on the ratio of the minimum luminance ratio among the luminances of the pixels 13R, 13G, and 13B. , the input tone value D _'R, D' respectively supply to _{13W G, D 'B, D} ' W is calculated, and the calculated said input tone value _{D 'R, D' G,} D 'B, D' W 4 color pixels 13R, 13G, 13B, 1 for each of the red, green, blue and white four color data signals. It is obtained so as to supply each W.

  Here, the maximum gradation luminance of the four colors 13R, 13G, 13B, and 13W of red, green, blue, and white is the gradation of the maximum gradation value in each of the pixels 13R, 13G, 13B, and 13W. Corresponding to the data (for example, when the input gradation data of three colors of red, green, and blue is data of 64 levels with gradation values of 0 to 63, gradation data of gradation value 63) It is the intensity | strength of the emitted light when a data signal is supplied.

That is, in this driving method, red to define a display color of one picture element 14, green, three-color gray data _D R of _blue, D G, each _{D B,} the respective gradation data _D R, _{D G} the total value of the brightness corresponding to the _{D B} for _{(R R L maxR + R G} L maxG + R B L maxB), red, green, three-color pixels 13R blue, 13G, maximum brightness of the sum of 13B _{(L maxR} + L _maxG + L _maxB ), the minimum luminance ratio R _min among the luminances of the red, green and blue pixels R, G and B, and the red, green and blue pixels 13R. , 13G, maximum brightness of the sum of 13B in _{(L maxR + L maxG + L} maxB) value obtained by multiplying the maximum luminance _{L maxW} white pixel 13W for the red, green, three-color gray data _D R of blue, D _G, the gradation corresponding to _{D B} The chromatography data luminance factor plus _{R R, R G, R B} , wherein these values red, green, three-color pixels 13R blue, 13G, maximum brightness of the sum of _{13B (L maxR + L maxG +} L maxB ) By subtracting the ratio of the luminance R ′ _W of the white pixel 13W to the display luminance ratios R ′ _R , R ′ _G , of the four-color pixels 13R, 13G, 13B, 13W of red, green, blue, and white. R ′ _B is obtained.

At this time, the luminance rate R ′ _W of the white pixel is the display luminance L ′ _R , L ′ _G , L ′ _B , L of the four-color pixels 13R, 13G, 13B, and 13W of red, green, blue, and white. 'of the _W, and pixel colors these values is the smallest value, the color of the pixel to be the second smallest value is if they are arranged adjacent to each other on the display screen, the 2 The display luminance L ′ _R , L ′ _G , and the display luminance L ′ _R , L ′ _G , of the pixels 13R, 13G, 13B, and 13W of the four colors of red, green, blue, and white are increased so that the luminance of the pixel that has the smallest value becomes as large as possible. L _'B, L' of the _W, and the pixels of these values is the smallest color, the color of the pixel to be the second smallest value is the case where on the display screen not adjacent to each other, The luminance of the pixel having the smallest value is set to be as large as possible.

In this driving method, the input gradation values D ′ _R , D ′ _G , and the like supplied to the pixels 13R, 13G, 13B, and 13W of the four colors of red, green, blue, and white, respectively, so as to satisfy the above condition. D ′ _B and D ′ _W are calculated, and the gradation signals D ′ _R , D ′ _G , D ′ _B and D ′ _W are converted into four color data signals of red, green, blue and white. The liquid crystal display element 1 is driven by supplying each of them.

More specifically, red for defining the display color of one picture element 14, green, three-color gray-scale data D _R of _blue, D _G, for each value of D _B, the luminance of the white pixel 13W The optimum value of R ′ _W is obtained, and based on the luminance rate R ′ _W of this white pixel,
R ′ _R = R _R {1 + tR _min (L _maxR + L _maxG + L _maxB ) / (R _R L _maxR + R _G L _maxG + R _B L _maxB )} − R ′ _W L _maxW / (L _maxR + L _maxG + L _maxB )
_{R 'G = R G {1} + tR min (L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} - R' W L maxW / (L maxR + L maxG + L maxB)
_{R 'B = R B {1} + tR min (L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} - R' W L maxW / (L maxR + L maxG + L maxB)
However, R ′ _R , R ′ _G , R ′ _B , and R ′ _W are red, green, blue, and white pixels 13R, 13G. The luminance when the voltages corresponding to the input gradation values D ′ _R , D ′ _G , D ′ _B , D ′ _W are applied to the display luminances L ′ _R , L ′ _G , L ′ _B , L ′ _W And the four-color pixels 13R, 13G. Red, green, blue, and white. The luminances of the maximum gradation values of 13B and 13W are set to the maximum gradation luminances L _maxR , L _maxG , L _maxB and L _maxW , _respectively , and the input gradation values D ′ _R , D ′ _G , D ′ _B and D ′ _W The luminance ratio when the corresponding voltage is applied is displayed as the luminance ratio R ′ _R = L ′ _R / L _maxR , R ′ _G = L ′ _G / L _maxG , R ′ _B = L ′ _B / L _maxB , R ′ _W = a _{L 'W} / L _maxW, red, green, three-color pixels 13R blue, 13G, the grayscale data _D R to _13B, D G, floors a luminance upon application of a voltage corresponding to the _{D B} the _L R tone data _brightness, L G, and _{L B,} the gradation data luminance _{L R,} L G, the gradation data luminance rate _{R R =} L _{R /} L maxR of _{L B, R G = L G} / L _maxG and R _B = L _B / L _maxB, and these gradation data luminance rates R _R and R _G , R _B is R _min, and t is a predetermined arbitrary value in the range of 0 or more and L _maxW / (L _{max R} + L _maxG + L _maxB ) or less.

The input gradation values D ′ _R , D ′ _G , D ′ _B , and D ′ _W supplied to the pixels 13R, 13G, 13B, and 13W of red, green, blue, and white are calculated so as to satisfy the respective equations. To do.

Here, red, green, three-color gradation data _D R of _blue, D G, for each value of _{D B,} the luminance ratio R of the white pixel 13W that optimum value is obtained _'W, the display brightness L' _{R , L 'G, L' B} , of the L _'W, and pixels of these values is the smallest color, the color of the pixel to be the second smallest value is, adjacent to each other on the display screen If it is arranged, it is substantially matched with the luminance of the pixel having the second smallest value, and among the display luminances L ′ _R , L ′ _G , L ′ _B and L ′ _W , When the pixel having the smallest value and the pixel having the second smallest value are not adjacent to each other on the display screen, the luminance and the substantial value of the pixel having the smallest value are substantially the same. To match.

In this driving method, the input grayscale values D ′ _R , D ′ _G , D ′ _B , and D ′ _W calculated in this way are used to display the four color data signals of red, green, blue, and white on the liquid crystal display. The liquid crystal display element 1 is driven by supplying each of the picture elements 14 of the element 1 to the pixels 13R, 13G, 13B, and 13W of the four colors red, green, blue, and white of the picture element 14, respectively. .

According to this driving method, the color of the same series and smallest color tone value and the brightness of the gradation value can be a relationship of a linear function, the red, green, blue, and white 4-color pixels 13R , 13G , 13B , and 13W reduce the uncomfortable feeling of image display in the liquid crystal display element 1 that constitutes one picture element 14, and the supplied gradation data D _R , D _G , D of three colors of red, green, and blue _A color image having good color reproducibility corresponding to _B can be displayed.

Furthermore, according to this driving method, the portion in which the color and the chromaticity and brightness are close spreads over a large area, a phenomenon that two colors appear to be alternately displayed including black is eliminated, discomfort of the display image Can be further reduced.

That is, the when the liquid crystal display device 1 is driven without obtaining an optimum value of the luminance factor R _'W white pixel 13W, the chromaticity and brightness and spread over a certain large area color close portion is a uniform color It looks like a patchwork in which two colors including black are alternately displayed, and the resolution is visually reduced, causing a sense of incongruity in the displayed image.

In contrast, the driving method is determined red, green, three-color gradation data D _R of _blue, D _G, the luminance factor R _'W optimal white pixel 13W for each value of D _B red, Since the input gradation values D ′ _R , D ′ _G , D ′ _B , and D ′ _W of the four colors of green, blue, and white are calculated, the phenomenon that two colors including black can be seen alternately is eliminated. .

The above driving method, red, green, gradation data _D 3 colors blue _R, D G, luminance factor coefficients below for each _{D B R fR,} R _fG, calculates the _{R fB,} these luminance factor coefficients R _{fR, R fG,} divided if each magnitude relation of the values of _{R fB,} the red, green, gradation data _D 3 colors blue _R, D G, luminance factor R _'W white pixel 13W of each _{D B} Can be applied to an actual driving method of the liquid crystal display element 1.

That is, the luminance factor coefficients R _fR , R _fG , R _fB are
_{R fR = R R {1 +} tR min (L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} (L maxR + L maxG + L maxB) / (2L maxR + L maxG + L maxB)
_{R fG = R G {1 +} tR min (L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} (L maxR + L maxG + L maxB) / (L maxR + 2L maxG + L maxB)
_{R fB = R B {1 +} tR min (L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} (L maxR + L maxG + L maxB) / (L maxR + L maxG + 2L maxB)
And define
(1) The smallest value of the luminance rate coefficients R _fR , R _fG , R _fB is the luminance rate coefficient R _fR , and the red pixel 13R corresponding to the luminance rate coefficient R _fR is a white pixel on the display screen. When the second smallest value among the values of the luminance factor coefficients R _fR , R _fG , and R _fB is the luminance factor factor R _fG , the display luminance L ′ _W of the white pixel 13 _W is _{White so} that the display luminance L ′ _G of the green pixel 13G corresponding to the second smallest luminance factor coefficient R _fG is substantially equal to the value (L ′ _W = L ′ _G or the value closest to L ′ _G ). setting the luminance ratio R _'W pixel 13W.

(2) The smallest value of the luminance rate coefficients R _fR , R _fG , and R _fB is the luminance rate coefficient R _fR , and the red pixel 13R corresponding to the luminance rate coefficient R _fR is a white pixel on the display screen. When the second smallest value among the values of the luminance factor coefficients R _fR , R _fG , and R _fB is the luminance factor factor R _fB , the display luminance L ′ _W of the white pixel 13 _W is White so that the display luminance L ′ _B of the blue pixel 13B corresponding to the second smallest luminance rate coefficient R _fB is substantially equal to the value (L ′ _W = L ′ _B or the value closest to L ′ _B ). setting the luminance ratio R _'W pixel 13W.

(3) The smallest value of the luminance rate coefficients R _fR , R _fG , and R _fB is the luminance rate coefficient R _fG , and the green pixel 13G corresponding to the luminance rate coefficient R _fG is a white pixel on the display screen. When the second smallest value among the values of the luminance factor coefficients R _fR , R _fG , and R _fB is the luminance factor factor R _fB , the display luminance L ′ _W of the white pixel 13 _W is White so that the display luminance L ′ _B of the blue pixel 13B corresponding to the second smallest luminance rate coefficient R _fB is substantially equal to the value (L ′ _W = L ′ _B or the value closest to L ′ _B ). setting the luminance ratio R _'W pixel 13W.

( 4) The smallest value of the luminance rate coefficients R _fR , R _fG , and R _fB is the luminance rate coefficient R _fG , and the green pixel 13G corresponding to the luminance rate coefficient R _fG is a white pixel on the display screen. When the second smallest value among the values of the luminance factor coefficients R _fR , R _fG , and R _fB is the luminance factor factor R _fR , the display luminance L ′ _W of the white pixel 13W is White so as to be a value substantially equal to the display luminance L ′ _R of the red pixel 13R corresponding to the second smallest luminance rate coefficient R _fR (L ′ _W = L ′ _R or the value closest to L ′ _R ). setting the luminance ratio R _'W pixel 13W.

( 5) The smallest value of the luminance rate coefficients R _fR , R _fG , and R _fB is the luminance rate coefficient R _fB , and the blue pixel 13B corresponding to the luminance rate coefficient R _fB is a white pixel on the display screen. adjacent to 13W, and the luminance factor coefficient _{R fR,} R _fG, if a small value to the second of the values of _{R fB} is luminance factor coefficient _{R fR,} the display brightness L _'W of the white pixel 13W, the White so as to be a value substantially equal to the display luminance L ′ _R of the red pixel 13R corresponding to the second smallest luminance rate coefficient R _fR (L ′ _W = L ′ _R or the value closest to L ′ _R ). setting the luminance ratio R _'W pixel 13W.

( 6) The smallest value among the values of the luminance rate coefficients R _fR , R _fG , and R _fB is the luminance rate coefficient R _fB , and the blue pixel 13B corresponding to the luminance rate coefficient R _fB is a white pixel on the display screen. adjacent to 13W, and the luminance factor coefficient _{R fR,} R _fG, if a small value to the second of the values of _{R fB} is luminance factor coefficient _{R fG,} the display brightness L _'W of the white pixel 13W, the _{White so} that the display luminance L ′ _G of the green pixel 13G corresponding to the second smallest luminance factor coefficient R _fG is substantially equal to the value (L ′ _W = L ′ _G or the value closest to L ′ _G ). setting the luminance ratio R _'W pixel 13W.

( 7) The smallest value of the luminance rate coefficients R _fR , R _fG , and R _fB is the luminance rate coefficient R _fR , and the red pixel 13R corresponding to the luminance rate coefficient R _fR is a white pixel on the display screen. When not adjacent to 13W, the display luminance L ′ _W of the white pixel 13W is the closest to the display luminance L ′ _R of the red pixel 13R (L ′ _W = L ′ _R or L ′ _R). Value) to set the luminance rate R ′ _W of the white pixel 13W.

( 8) The smallest value among the luminance rate coefficients R _fR , R _fG , and R _fB is the luminance rate coefficient R _fG , and the green pixel 13G corresponding to the luminance rate coefficient R _fG is a white pixel on the display screen. When not adjacent to 13W, the display luminance L ′ _W of the white pixel 13W is substantially the same as the display luminance L ′ _G of the green pixel 13G (L ′ _W = L ′ _G or closest to L ′ _G). Value) to set the luminance rate R ′ _W of the white pixel 13W.

( 9) The smallest value of the luminance rate coefficients R _fR , R _fG , and R _fB is the luminance rate coefficient R _fB , and the blue pixel 13B corresponding to the luminance rate coefficient R _fB is a white pixel on the display screen. When not adjacent to 13W, the display luminance L ′ _W of the white pixel 13W is the closest to the display luminance L ′ _B of the blue pixel 13B (L ′ _W = L ′ _B or L ′ _B). Value) to set the luminance rate R ′ _W of the white pixel 13W .

As described above, in any of the cases (1) to (9), the display luminance L ′ _W of the white pixel 13W is equal to the display luminance L ′ _R , L ′ _G , of the pixels 13R, 13G, and 13B of other colors. L ′ is set to a value substantially equal to any of _B. Here, the display luminance L ′ _W of the white pixel 13W is set to the largest value among the display luminances L ′ _R , L ′ _G , and L ′ _B of the pixels 13R, 13G, and 13B of other colors. preferable.

(First embodiment)
Hereinafter, specific examples of the driving method of the present invention will be described. 3, for defining a display color of one picture element in the first embodiment, red, green, three colors of blue gradation data D _R, D _G, of the pixels to be driven in response to the D _B An example of selection is shown.

This example red for defining the display color of one picture element, red green, three-color gradation data D _R of _blue, D _G, corresponding to the D _B, constitute one picture element , Green, blue, and white pixels 13R, 13G, 13B, and 13W are driven.

That is, in this embodiment, the pixel arrangement as shown in FIG. 3, that is, red, green, blue, and white pixels 13R, 13G, 13B, and 13W are arranged in the same order for each row, for example, red pixels 13R, A plurality of pictures are formed by four red, green, blue, and white pixels 13R, 13G, 13B, and 13W adjacent to each other in each row, arranged alternately in the order of green pixels 13G, blue pixels 13B, and white pixels 13W. In the pixel array constituting the elements, the four pixels 13R, 13G, 13B, red, green, blue, and white constituting one pixel in each row, that is, four pixels in a region surrounded by a thick solid line in the figure. the 13W, gradation data _D R of one pixel _worth, and D G, drive pixel group 24 corresponding to the _{D B,} 4 single pixel 13R of these driving pixel groups 24, 13G, 13B, respectively 13W, 1 single picture Red for defining the color of green, three-color gradation data D _R of _blue, D _G, driven in response to D _B.

  The red, green, blue, and white pixels 13R, 13G, 13B, and 13W have gradation values of data signals supplied to the pixels 13R, 13G, 13B, and 13W, and gradations of the data signals. It is formed so that the luminance obtained by applying a voltage according to the value is proportional.

As in the first embodiment, when the four pixels 13R, 13G, 13B and 13W of red, green, blue and white constituting one picture element are driven as one drive pixel group 24, red for defining the pixels of the display color, green, three-color gradation data _D R of _blue, D G, red corresponding to _{D B,} green and blue three color pixels 13R, 13G, 13B luminance of The rate is expressed by R _R = D _R / D _f , R _G = D _G / D _f , and R _B = D _B / D _f (D _f is the maximum gradation value).

On the other hand, the input gradation values D ′ _R , D ′ _G , D ′ _B , and D ′ _W supplied to the four color pixels 13R, 13G, 13B, and 13W of red, green, blue, and white are supplied red. , green, gray-scale data _D R 3 colors of blue _is defined by D G, from _{D B} as follows.

That is,
The 3-color gray-scale data _{D R,} D G, when _{D B} are all _{0 (D R = D G =} D B = 0), red, green, blue, white 4 color pixels 13R, 13G, 13B , 13W respectively supplied to the four input gradation values D ′ _R , D ′ _G , D ′ _B , D ′ _W
D' _R = D' _G = D' _B = D' _W = 0
Determined.

Meanwhile, the three-color gray-scale data _{D R,} D G, except when all of _{D B} 0,
The input gradation value D ′ _R supplied to the red pixel 13R is
_{D R {1 + tR min (} L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} - C'L maxW / (L maxR + L maxG + L maxB)
To an integer value,
The input gradation value D′ _G supplied to the green pixel 13G is
D _G {1 + tR _min (L _maxR + L _maxG + L _maxB ) / (R _R L _maxR + R _G L _maxG + R _B L _maxB )} − C′L _maxW / (L _maxR + L _maxG + L _maxB )
To an integer value,
The input gradation value D ′ _B supplied to the blue pixel 13B is
D _B {1 + tR _min (L _maxR + L _maxG + L _maxB ) / (R _R L _maxR + R _G L _maxG + R _B L _maxB )} − C′L _maxW / (L _maxR + L _maxG + L _maxB )
To an integer value,
The input gradation value D′ _W supplied to the white pixel 13W is a value obtained by converting C ′ into an integer,
Each is defined.

  Here, integerization means that processing such as rounding off, rounding down, or rounding up is performed.

  However, C ′ is determined as follows.

The first tone value coefficients D _fR , D _fG , D _fB are
_{D fR = D R {1 +} tR min (L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} (L maxR + L maxG + L maxB) / (2L maxR + L maxG + L maxB)
_{D fG = D G {1 +} tR min (L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} (L maxR + L maxG + L maxB) / (L maxR + 2L maxG + L maxB)
_{D fB = D B {1 +} tR min (L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} (L maxR + L maxG + L maxB) / (L maxR + L maxG + 2L maxB)
And define
The second gradation value coefficients D _mR , D _mG , and D _{m B} are _expressed as D _mR = D _R {1 + tR _min (L _maxR + L _maxG + L _maxB ) / (R _R L _maxR + R _G L _maxG + R _B L _maxB )}
D _mG = D _G {1 + tR _min (L _maxR + L _maxG + L _maxB ) / (R _R L _maxR + R _G L _maxG + R _B L _maxB )}
D _mB = D _B {1 + tR _min (L _maxR + L _maxG + L _maxB ) / (R _R L _maxR + R _G L _maxG + R _B L _maxB )}
And define
These second gradation value coefficient _{D mR, D mG,} of _{D m B,} the smallest value as the _{D mmin,}
These second gradation value coefficient _{D mR, D mG,} of _{D m B,} the largest value as _{D mmax,}
The first gradation value coefficient _{D fR, D fG,} of _{D fB,} the smallest value _{D fR} or _{D fB,} when the second smallest value of _{D fG,}
If D _{m min} <D _fG ,
_{C '= D m min (L} maxR + L maxG + L maxB) / L maxW
In the case of _{D mmax} -D _f> D _fG,
C ′ = (D _{m max} −D _f ) (L _maxR + L _maxG + L _maxB ) / L _{maxW
D m min} <D _fG, and, _{D m} max _{-D f>} otherwise _{D fG C '= D fG (} L maxR + L maxG + L maxB) / L maxW
The first gradation value coefficient _{D fR, D fG,} of _{D fB,} the smallest value _{D fR,} when the second smallest value of _{D fB,}
If D _{m min} <D _fB ,
_{C '= D m min (L} maxR + L maxG + L maxB) / L maxW
If D _{m max} −D _f > D _fB ,
_{C '= (D m max -Df} ) (L maxR + L maxG + L maxB) / L maxW
When D _{m min} <D _fB and D _{m max} −D _f > D _fB ,
C ′ = D _fB (L _maxR + L _maxG + L _maxB ) / L _maxW
The first gradation value coefficient _{D fR, D fG,} of _{D fB,} the smallest value _{D fB,} when the second smallest value of _{D fR,}
If D _{m min} <D _fR ,
_{C '= D m min (L} maxR + L maxG + L maxB) / L maxW
If D _{m max} <D _fR ,
C ′ = (D _{m max} −D _f ) (L _maxR + L _maxG + L _maxB ) / L _maxW
If D _{m min} <D _fR and D _{m max} <D _fR ,
C ′ = D _fR (L _maxR + L _maxG + L _maxB ) / L _maxW
The first gradation value coefficient _{D fR, D fG,} when one of _{D fB,} the smallest value of _{D fG,}
If D _{m min} <D _fG ,
_{C '= D m min (L} maxR + L maxG + L maxB) / L maxW
If D _{m max} −D _f > D _fG ,
C ′ = (D _{m max} −D _f ) (L _maxR + L _maxG + L _maxB ) / L _maxW
When D _{m min} <D _fG and D _{m max} −D _f > D _fG ,
C ′ = D _fG (L _maxR + L _maxG + L _maxB ) / L _maxW
Respectively, to calculate input gradation values D ′ _R , D ′ _G , D ′ _B , D ′ _W to be supplied to the pixels 13R, 13G, 13B, 13W of the respective colors of red, green, blue, and white, The calculated input gradation values D ′ _R , D ′ _G , D ′ _B , and D ′ _W are used as the four color data signals of red, green, blue, and white of the one drive pixel group 24. Supply to each pixel.

According to this embodiment, the liquid crystal display element of the pixel array shown in FIG. 3, the supplied red, green, gray-scale data D _R three colors _blue, D _G, of the color reproducibility corresponding to D _B A good color image can be displayed.

  FIG. 4 shows emission from the four color pixels 13R, 13G, 13B, and 13W when the liquid crystal display element having the pixel arrangement of FIG. 3 is driven according to the first embodiment. The spectral characteristics of four colors of light of red, green, blue, and white are shown.

In the above first embodiment, red for defining the display color of one picture element, green, three-color gradation data D _R of _blue, D _G, the pixels driven corresponding to the D _B The selection is made according to the pixel arrangement of the liquid crystal display element.

FIGS. 5 and 6 respectively show other pixel selection examples in the first embodiment. In the example of FIG. 5, the four-color pixels 13R, 13G, 13B, red, green, blue, and white are shown. 13W are alternately arranged in the same order for each row, and the pixels of the same color in the pixel arrangement of one of the two adjacent rows and the pixel arrangement of the other row are arranged with a 1.5 pixel pitch shift. In each pixel row, four pixels 13R, 13G, 13B, and 13W that are adjacent to each other in red, green, blue, and white are arranged in a thick solid line. Four pixels, that is, four pixels 13R, 13G, 13B, 13W of red, green, blue, and white constituting one picture element for each row correspond to each gradation data DR, DG, DB for one picture element. The driving pixel group 24 is used.

In the example of FIG. 6, one of two adjacent rows has a pixel of two colors among four colors of red, green, blue, and white, for example, a red pixel 13R and a green pixel 13G. Are alternately arranged, and the other row of the four colors of red, green, blue, and white, for example, the blue pixel 13B and the white pixel 13W are alternately arranged in the other row. In each of two adjacent rows, in a pixel array comprising a plurality of picture elements comprising four pixels 13R, 13G, 13B, 13W of red, green, blue, and white in the two rows and two columns, Four pixels in a region surrounded by a thick solid line in the drawing, that is, four pixels 13R, 13G, 13B, and 13W of red, green, blue, and white constituting one picture element for every two adjacent rows are represented by 1 gradation data _D R of the pixel _fraction, D G, and a drive pixel group 24 corresponding to the _{D B} There.

The pixel selection example as in FIG. 6, one pixel worth of each gray scale data D _R, D _G, red one drive pixel group 24 corresponding to the D _B, green, blue, and four pixels 13R white , 13G, 13B, and 13W are adjacent to each other in the row direction, the column direction, and the oblique direction, but the shape of the pixels 13R, 13G, 13B, and 13W of these colors is an elongated rectangular shape along the column direction. Since each pixel 13R, 13G, 13B, and 13W have mutually different degrees of adjacency (lengths of adjacent parts), pixels having a strong degree of adjacency, that is, red pixel 13R, green pixel 13G, and blue pixel 13B The white pixels 13W are regarded as pixels adjacent to each other, and the pixels having a low degree of adjacency, that is, the red pixel 13R and the blue pixel 13B, the green pixel 13G and the white pixel 13W, and the red image are displayed. The 13R and white pixel 13W by regarding a pixel not adjacent each can be applied to the driving method.

Further, in the pixel selection example as shown in FIG. 6, the red pixel 13R, the blue pixel 13B, the green pixel 13G, and the white color are compared with the distance between the centers of the red pixel 13R and the green pixel 13G and the blue pixel 13B and the white pixel 13W. since the pixel 13W, and the distance between the centers of the red pixel 13R and the white pixel 13W large, pixel 13R of red and green, 13G and between blue and white and the pixel 13B, 13W each other adjacent respective red and blue pixels 13R, 13B, pixel 13G of the green and white, 13W, and the pixel 13R of red and white, regarded as 13W are not adjacent, may be applied to the driving method.

(Second embodiment)
The above first embodiment, red for defining the display color of one picture element, green, three-color gradation data D _R of _blue, D _G, corresponding to the D _B, one picture The four pixels 13R, 13G, 13B, and 13W of red, green, blue, and white constituting the element are driven. The red, green, and blue pixels for defining the display color of the one picture element are driven. 3-color gradation data D _R, D _G, selecting the number of pixels to be driven in response to the D _B may be other numbers.

7, in the second embodiment, red for defining the display color of one picture element, green, three-color gradation data D _R of _blue, driven corresponding to D _G, D _B shows an example of selecting picture element, this embodiment is red for defining the display color of one picture element, green, three-color gradation data D _R of _blue, D _G, corresponding to the D _B Thus, two of the four pixels 13R, 13G, 13B, and 13W of red, green, blue, and white constituting one picture element are driven.

That is, in this embodiment, the pixel arrangement as shown in FIG. 7, that is, the four-color pixels 13R, 13G, 13B, and 13W of red, green, blue, and white are alternately arranged in the same order for each row. In each pixel, in a pixel array in which a plurality of picture elements are formed by four adjacent pixels 13R, 13G, 13B, and 13W of red, green, blue, and white, two regions in a region surrounded by a thick solid line in the figure pixel, i.e. red constituting one picture element of each row, green, blue, and white four pixels 13R, 13G, 13B, 2 a pixel 13R with each other adjacent red and green of 13W, and 13G other mutually adjacent blue and two pixels 13B of white, gradation data _D R of one pixel worth and 13W, _{respectively,} D G, drive pixel group 25a corresponding to _{D B,} and 25b, while Two of the drive pixel groups 25a Pixel 13R, and 13G, 2 two pixels 13B of the other drive pixel groups 25b, and 13W, respectively, red for defining the display color of one picture element, green, gradation data of three colors of blue _{D R} , _D G, corresponding to the _{D B} drive.

In this embodiment, each gradation of red, green, and blue for defining the display color of one picture element in the two pixels 13R, 13G of red and green of the one drive pixel group 25a. data _{D R,} D G, the input gradation value calculated as described above based on _{D B D 'R, D'} G, D 'B, D' input gradation value D between the red and green of the _W ' To supply data signals of two colors _R and D' _G , respectively, and to define the display color of the next one picture element in the two pixels 13B and 13W of blue and white of the other drive pixel group 25b red, green, gradation data _D R three colors _blue, D G, _D input tone value D _'R, D' calculated as described above based on _{B G, D 'B, D} ' W of supplies out of the blue and the input tone value D _'B of the _white, two-color data signal D'W, respectively.

In the above second embodiment, red for defining the display color of one picture element, green, three-color gradation data D _R of _blue, D _G, the pixels driven corresponding to the D _B The selection is made according to the pixel arrangement of the liquid crystal display element.

FIGS. 8 and 9 show examples of selection of other pixels in the second embodiment. In the example of FIG. 8, the four colors of pixels 13R, 13G, 13B, red, green, blue, and white are shown. 13W are alternately arranged in the same order for each row, and the pixels of the same color in the pixel arrangement of one row and the pixel arrangement of the other row of the two adjacent rows are arranged with a shift of 2 pixel pitches. 2 pixels in a region surrounded by a thick solid line in the figure in a pixel array comprising a plurality of picture elements composed of four pixels 13R, 13G, 13B, and 13W of red, green, blue, and white adjacent to each other, that red constituting one picture element of each row, green, blue, and white four pixels 13R, 13G, 13B, 2 a pixel 13R with each other adjacent red and green of 13W, and 13G, other two pixels 13B of the blue and white adjacent each other, and 13W, Gradation data _D R of each one pixel _worth, D G, drive pixel group 25a corresponding to _{D B,} is set to 25b.

In the example of FIG. 9, pixels in two colors among four colors of red, green, blue, and white, for example, a red pixel 13 </ b> R and a green pixel 13 </ b> G, are displayed in one of two adjacent rows. Are alternately arranged, and the other row of the four colors of red, green, blue, and white, for example, the blue pixel 13B and the white pixel 13W are alternately arranged in the other row. In each of two adjacent rows, in a pixel array comprising a plurality of picture elements comprising four pixels 13R, 13G, 13B, 13W of red, green, blue, and white in the two rows and two columns, Two pixels in a region surrounded by a thick solid line in the drawing, that is , two pixels 13R and 13G of red and green adjacent to each other in one row, and two pixels 13B of blue and white adjacent to each other in the other row , response and 13W, the gradation data _D R of each one pixel _worth, D G, the _{D B} Driving the pixel group 25a has, is set to 25b.

(Third embodiment)
10, for defining one pixel of the display color of the third embodiment red, green, three colors of blue gradation data D _R, D _G, of the pixels to be driven in response to the D _B It shows the selected択例.

This example red for defining the display color of one picture element, green, three-color gradation data D _R of _blue, D _G, corresponding to the D _B, the eight pixels corresponding to two The pixel is driven.

In other words, in this embodiment, the pixel arrangement as shown in FIG. 10, that is, the four-color pixels 13R, 13G, 13B, and 13W of red, green, blue, and white are alternately arranged in the same order for each row. 8 pixels in a region surrounded by a thick solid line in a pixel array in which a plurality of picture elements are configured by four pixels 13R, 13G, 13B, and 13W of red, green, blue, and white adjacent to each other for each row. That is, four pixels 13R, 13G, 13B, and 13W of red, green, blue, and white that constitute one picture element in one of two adjacent rows, and one picture element in the other row. component red, green, blue, and white four pixels 13R, 13G, 13B, and 13W, a total of eight pixels, each gradation data _D R of one pixel _worth, D G, drive corresponding to _{D B} A pixel group 26, and these drive pixel groups 26 , Green, blue, and white for two pixels 13R, 13R, 13G, 13G, 13B, 13B, 13W, and 13W, red, green, and blue for defining the display color of one picture element Data signals of input gradation values D′ R, D′ G, D′ B, and D′ W calculated as described above based on the gradation data DR, DG, and DB of the three colors are supplied.

In this embodiment, the data signal supplied two red pixels 13R, the 13R of the one driving the pixel group 26, the signal of the same gray-scale data _{D R,} two green pixels 13G, the data signal supplied to 13G are signal of the same gray-scale data _{D G,} 2 one blue pixel 13B, the data signal supplied to 13B, the signal of the same gray-scale data _{D B,} 2 one white pixel 13W, the data signal supplied to 13W, the same gradation data _DW signal.

(Other examples)
The driving method of the present invention is not limited to the liquid crystal display elements having the pixel arrangement shown in FIGS. 3 and 5 to 10, and can be applied to driving liquid crystal display elements having various pixel arrangements.

  That is, in a pixel array in which red and green, red and blue, red and white, green and blue, green and white, and blue and white pixels are all adjacent, the degree of adjacent is strong (the adjacent portion is long). Pixels are considered as adjacent pixels, and pixels with low degree of adjacency (short adjacent portions) are considered as non-adjacent pixels, or the distance between the centers of adjacent pixels is short The above driving method can be applied by regarding the pixels as adjacent pixels and regarding the pixels having a long distance between the centers as non-adjacent pixels.

  The driving method of the present invention is not limited to a liquid crystal display element in which a plurality of pixels of four colors of red, green, blue, and white are arranged in a predetermined order, but four of red, green, blue, and white. The present invention can also be applied to driving other display elements in which a plurality of color pixels are arranged in a predetermined order, for example, an organic EL (electroluminescence) display element.

The block diagram of a display apparatus. FIG. 3 is a cross-sectional view of a part of a liquid crystal display element. Shows red for defining one pixel of the display color of the first embodiment of the present invention, green, three colors selected択例of pixels to be driven in response to the gradation data of the blue. Light of four colors of red, green, blue and white respectively emitted from pixels of four colors of red, green, blue and white when the liquid crystal display element having the pixel arrangement of FIG. 3 is driven according to the first embodiment. FIG. The figure which shows the other example of pixel selection in a 1st Example. The figure which shows the other example of pixel selection in a 1st Example. The figure which shows the example of selection of the pixel driven corresponding to each gradation data of three colors of red, green, and blue for defining the display color of one picture element in 2nd Example of this invention. The figure which shows the other pixel selection example in a 2nd Example. The figure which shows the other pixel selection example in a 2nd Example. FIG. 10 is a block diagram of pixels driven corresponding to each gradation data of three colors of red, green, and blue for defining a display color of one picture element, showing a third embodiment of the present invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Liquid crystal display element, 13R ... Red pixel, 13G ... Green pixel, 13B ... Blue pixel, 13W ... White pixel, 14 ... Picture element, 15 ... Drive means, 24, 25a, 25b, 26 ... Drive pixel group.

Claims (3)

A plurality of pixels of four colors of red, green, blue, and white are arranged in a predetermined order, and one picture element is formed by four pixels of each color of red, green, blue, and white adjacent to each other. In a method of driving a display element to be configured based on supplied gradation data of three colors of red, green, and blue,
Red for defining the display color of one picture element, green, three-color gradation data D _R of _blue, D _G, for each value of D _B,
R ′ _R = R _R {1 + tR _min (L _maxR + L _maxG + L _maxB ) / (R _R L _maxR + R _G L _maxG + R _B L _maxB )} − R ′ _W L _maxW / (L _maxR + L _maxG + L _maxB )
_{R 'G = R G {1} + tR min (L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} - R' W L maxW / (L maxR + L maxG + L maxB)
_{R 'B = R B {1} + tR min (L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} - R' W L maxW / (L maxR + L maxG + L maxB)
However, R ′ _R , R ′ _G , R ′ _B , and R ′ _W are input gradation values D ′ _R , D ′ _G , D ′ _B , and D ′ to pixels of red, green, blue, and white colors, respectively. The luminance when the voltage corresponding to _W is applied is the display luminance L ′ _R , L ′ _G , L ′ _B , L ′ _W , and the maximum gradation value of each of the four colors of red, green, blue and white pixels. _Is the maximum gradation luminance L _maxR , L _maxG , L _maxB , L _maxW, and the luminance when a voltage corresponding to the input gradation values D ′ _R , D ′ _G , D ′ _B , D ′ _W is applied. The display luminance ratios R ′ _R = L ′ _R / L _maxR , R ′ _G = L ′ _G / L _{max G} , R ′ _B = L ′ _B / L _{max B} , R ′ _W = L ′ _W / L _{max W} red, green, blue, and gradation data D to each color of a pixel of white _R, D _G, the gradation data luminance is a luminance when applying a voltage corresponding to the _{D B L R, L G,} L And _B, and the gray-scale data luminance _{L R, L G,} the gradation data luminance ratio _{L B R R = L R /} L maxR, R G = L G / L maxG, R B = L B / L maxB The gradation data luminance rate is R _R , R _G , R _B , the minimum value is R _min , t is greater than 0 , and L _maxW / (L _{max R} + L _maxG + L _maxB ) or less. It is an arbitrary value set in advance,
And, display brightness ratio R of the white pixel _'W red, green, blue, and the display brightness L of each color of the pixels of the white' _R, L _'G, L' _B, of the L _'W, these values pixels but made the color of pixels to be the smallest value, and second-color becomes a small value pixel, and but if they are arranged adjacent to each other on the front示画surface is the second smallest value the And a value that substantially matches the luminance rate of
The display luminance _{L 'R, L' G,} L 'B, L' and pixels, the colors of these values is the smallest value of _W, and the color of the pixel to be the second smallest value, but TABLE If they are not adjacent to each other on the display screen, the value is substantially matched with the luminance rate of the pixel having the smallest value, and red, green, blue, and white are set so as to satisfy the respective expressions. input tone value D _'R, D' supplied to the respective colors of the pixel _G, D _'B, D' calculates _W, these tone values _{D 'R, D' G,} D 'B, D' W of Supply four color data signals to red, green, blue and white pixels respectively ;
And a display element driving method. Brightness rate coefficient _{R fR, R fG,} the _{R fB,
R fR = R R {1 +} tR min (L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} (L maxR + L maxG + L maxB) / (2L maxR + L maxG + L maxB)
_{R fG = R G {1 +} tR min (L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} (L maxR + L maxG + L maxB) / (L maxR + 2L maxG + L maxB)
_{R fB = R B {1 +} tR min (L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} (L maxR + L maxG + L maxB) / (L maxR + L maxG + 2L maxB)
When it is defined as,
Display luminance factor R _'W white pixel, the luminance factor coefficient R _{fR, R fG,} when one of the values of R _fB, the pixels of the smallest value adjacent white pixels on the display screen, the luminance rate coefficient is set to the display brightness index substantially equal pixel of smaller Secondly,
The luminance factor coefficient R _{fR, R fG,} of the values of R _fB, most when the smallest value of the pixel is not adjacent to the white pixel on the display screen, display brightness index substantially the pixels of the smallest value was set to equal,
The method of driving a display element according to claim 1 . A plurality of pixels of four colors of red, green, blue, and white are arranged in a predetermined order, and one picture element is formed by four pixels of each color of red, green, blue, and white adjacent to each other. a display device which constitutes the supplied red, green, three-color gray-scale data D _R of _blue, D _G, red on the basis of D _B, respectively supply green, blue, and four-color pixels of white 4 In a method of driving by generating two input gradation values D ′ _R , D ′ _G , D ′ _B and D ′ _W and supplying them to each pixel,
The four color pixels of red, green, blue, and white have the input gradation value supplied to each pixel and the luminance obtained by applying a voltage according to the input gradation value. Formed to be proportional,
Red corresponding to the supplied gradation data, green, _R three color gradation data luminance of the pixels of the blue, respectively _{R = D R / D f,} R G = D G / D f, R B = D B / _{D f (D} f is the maximum value of gradation) expressed in, the gradation level data luminance factor _{R R,} R G, the minimum value of _{R B} and _{R min,}
When gray-scale data _{D R,} D G, is _{D B} all 0,
The four input gradation values D ′ _R , D ′ _G , D ′ _B and D ′ _W are all set to 0,
Grayscale data _{D R,} D G, when at least one of _{D B} other than 0,
The input tone value D′ _R is
_{D R {1 + tR min (} L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} - C'L maxW / (L maxR + L maxG + L maxB)
To an integer value,
The input tone value D′ _G is
D _G {1 + tR _min (L _maxR + L _maxG + L _maxB ) / (R _R L _maxR + R _G L _maxG + R _B L _maxB )} − C′L _maxW / (L _maxR + L _maxG + L _maxB )
To an integer value,
The input tone value D′ _B is
D _B {1 + tR _min (L _maxR + L _maxG + L _maxB ) / (R _R L _maxR + R _G L _maxG + R _B L _maxB )} − C′L _maxW / (L _maxR + L _maxG + L _maxB )
To an integer value,
The input tone value D′ _W is a value obtained by converting C ′ into an integer.
However , R ′ _R , R ′ _G , R ′ _B , and R ′ _W are input gradation values D ′ _R , D ′ _G , D ′ _B , and D ′ to pixels of red, green, blue , and white colors, respectively. The luminance when the voltage corresponding to _W is applied is the display luminance L ′ _R , L ′ _G , L ′ _B , L ′ _W , and the maximum gradation value of each pixel of each color of red, green, blue , and white The luminance ratio when the voltages corresponding to the input gradation values D ′ _R , D ′ _G , D ′ _B , and D ′ _W are applied with the maximum gradation luminances L _maxR , L _maxG , L _maxB , and L _maxW R ′ _R = L ′ _R / L _max R, R ′ _G = L ′ _G / L _{max G} , R ′ _B = L ′ _B / L _{max B} , R ′ _W = L ′ _W / L _{max W} , red , green, wherein the respective colors of the pixels of the blue gradation data _{D R,} D G, the gradation data luminance is a luminance when applying a voltage corresponding to the _{D B L R, L G,} L B And, a t greater than 0, and advance any of the values defined for _{L maxW / (L max R +} L maxG + L maxB) following ranges,
Where C ′ is
The first tone value coefficients D _fR , D _fG , D _fB are
_{D fR = D R {1 +} tR min (L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} (L maxR + L maxG + L maxB) / (2L maxR + L maxG + L maxB)
_{D fG = D G {1 +} tR min (L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} (L maxR + L maxG + L maxB) / (L maxR + 2L maxG + LmaxB)
_{D fB = D B {1 +} tR min (L maxR + L maxG + L maxB) / (R R L maxR + R G L maxG + R B L maxB)} (L maxR + L maxG + L maxB) / (L maxR + L maxG + 2L maxB)
And define
The second gradation value coefficients D _mR , D _mG , and D _{m B} are set to D _mR = D _R {1 + tR _min (L _maxR + L _maxG + L _maxB ) / (R _R L _maxR + R _G L _maxG + R _B L _maxB )}
D _mG = D _G {1 + tR _min (L _maxR + L _maxG + L _maxB ) / (R _R L _maxR + R _G L _maxG + R _B L _maxB )}
D _mB = D _B {1 + tR _min (L _maxR + L _maxG + L _maxB ) / (R _R L _maxR + R _G L _maxG + R _B L _maxB )}
And define
The smallest value among these second gradation value coefficients D _mR , D _mG and D _{m B} is D _{m min} , and the second gradation value coefficient D _mR , D _mG and D _{m B} is When the largest value is D _{m max} ,
First gradation value coefficient _{D fR, D fG,} of _{D fB,} the smallest value _{D fR} or _{D fB,} is the second smallest value is when _{D fG,}
If D _{m min} <D _fG ,
_{C '= D m min (L} maxR + L maxG + L maxB) / L maxW
If D _{m max} −D _f > D _fG ,
C ′ = (D _{m max} −D _f ) (L _maxR + L _maxG + L _maxB ) / L _{maxW
D mmin} <D _fG, and, D _{m max} -D _f> otherwise _{D fG,}
C ′ = D _fG (L _maxR + L _maxG + L _maxB ) / L _maxW
First gradation value coefficient _{D fR, D fG,} of _{D fB,} the smallest value _{D fR,} is the second smallest value is when _{D fB,}
If D _{m min} <D _fB ,
_{C '= D m min (L} maxR + L maxG + L maxB) / L maxW
If D _{m max} −D _f > D _fB ,
C ′ = (D _{m max} −D _f ) (L _maxR + L _maxG + L _maxB ) / L _{maxW
D m min} <D _fB, and, D _{m max} -D _f> otherwise _{D fB,}
C ′ = D _fB (L _maxR + L _maxG + L _maxB ) / L _maxW
First gradation value coefficient _{D fR, D fG,} of _{D fB,} the smallest value _{D fB,} is the second smallest value is when _{D fR,}
If D _{m min} <D _fR ,
_{C '= D m min (L} maxR + L maxG + L maxB) / L maxW
If D _{m max} −D _f > D _{f R} ,
C ′ = (D _{m max} −D _f ) (L _maxR + L _maxG + L _maxB ) / L _{maxW
D m min} <D _fR, and, D _{m max} -D _f> otherwise _{D fR,}
C ′ = D _fR (L _maxR + L _maxG + L _maxB ) / L _maxW
First gradation value coefficient _{D fR, D fG,} when one of the _{D fB,} the smallest value of _{D fG,}
If D _{m min} <D _fG ,
_{C '= D m min (L} maxR + L maxG + L maxB) / L maxW
If D _{m max} −D _f > D _fG ,
C ′ = (D _{m max} −D _f ) (L _maxR + L _maxG + L _maxB ) / L _{maxW
D m min} <D _fG, and, D _{m max} -D _f> otherwise _{D fG,}
C ′ = D _fG (L _maxR + L _maxG + L _maxB ) / L _maxW
And the calculated input gradation values D ′ _R , D ′ _G , D ′ _B , and D ′ _W are used as the four color data signals of red, green, blue, and white, respectively. Supply to each of the pixels ,
And a display element driving method.

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