TW200842814A - Liquid crystal display apparatus, liquid crystal display panel and driving method thereof - Google Patents

Abstract

A LCD panel receives a plurality of pixel data, each of the pixel data at least has a first color sub-pixel data and a second color sub-pixel data. The LCD panel includes a yellowish correcting module and a pixel array. The yellowish correcting module transforms the first color sub-pixel data and the second color sub-pixel data into a first data driving signal and a second data driving signal according to a first relationship and a second relationship, respectively. The first relationship is different from the second relationship. The pixel array has a plurality of pixels. Each of the pixels at least has a first color sub-pixel and a second color sub-pixel. The first color sub-pixel and the second color sub-pixel are driven by the first data driving signal and the second data driving signal, respectively.

Description

200842814 IX. Description of the invention: [Technical field to which the invention pertains] The present invention relates to a display device, a method for pulling a Sil Μ #夏" item, and a driving method thereof, in particular, a method for displaying a liquid crystal display. Non-panel and its drive [Prior Art] With the development of display technology, the plane is widely used by people, and the liquid crystal, the mouthful has been wide and the more features of coffee, has gradually replaced the traditional heart = official two devices, And applied to many kinds of electronic products:: group liquid: the daily display device has at least - liquid crystal display panel and a back::: Figure i, the conventional liquid crystal display surface 3 (4) Unit 12. The crucible has a plurality of alizarins 110, and each of the crucibles is known as a blue book JB, a red alizarin ruler, and a green alizarin g. The U system is based on at least one of the data. The array U is displayed in conjunction with the operation of the backlight and the liquid crystal. However, the liquid crystal display panel # has some technical problems, such as a wide viewing angle. Said, perspective The gamma characteristic is related to the relationship between the gray scale of the gammM button and the light transmittance (or brightness), and the gray scale of the liquid crystal display panel 1 is the light transmittance of the light transmittance. Characteristic song $ 6 200842814 back. Please see the picture 2, the red corresponding curve u, the green corresponding curve L 2, the blue corresponding curve L 3 represents the red, green and blue light of the human eye facing the liquid crystal display panel i And the red corresponding curve μ, the ^ color corresponding curve L5, the blue corresponding curve L6 represents the human eye side view (for example, J is 60 degrees for the front view), the red, green and light penetration of the liquid crystal display panel i Rate: Among them, 'because of the curve "..., "different from the curve U, check L3" results in the appearance of the facet of the human eye side view liquid crystal display panel, which is prone to color shift phenomenon. In order to solve the above problems, there is a low w wide-shrft design in the prior art. Referring to FIG. 3, another liquid crystal display panel 1 of the prior art, the liquid surface of the liquid crystal - the color of the liquid surface, the name + 'f day and day" is not different from the panel 1 , each (four) ', green The 昼素〇's division is divided into a younger one-region L, and a first-F(1) gamma. CK. For example, when Book 辛 8bu' is divided into 255 gray-scale book-bean materials, the gray-scale is increased to 155 gray-scale, then the '- prime system drives the first-region L, which is raised from the dark state to Bright state 2 Dark state. When the pixel data is made of W gray: ^ . Λ ^(1)', the driving unit 12 is driven to correspond to the first region D from the dark state to the bright state. Ascending to... At this time, the first-region L is still maintained, and the tea is shown in Fig. 4, and the characteristic curve of the gray scale to light transmittance of the liquid data is shown in the second panel: '^corresponding curve L4' , green corresponding curve,: red with the curve of Figure 2 T / 1 匕耵 curve L6, should curve L4 'green corresponding curve L5 and blue to 200842814 should be compared with curve L6, curve L4,, L5 , , L6, and the deviation from the curves u, L2, L3 are small, so the color shift can be reduced. It is worth noting here that the curves [4, 1, 1 , , [6, respectively have a turning point (::, 4, 〇:, 5, C 6 /, medium, the turning point occurs in the second area D, starting From dark state to bright state (155~156 gray level). In addition, 'generally, because of the dependence between liquid crystal transmittance and light wavelength- or other factors, when the halogen data is low Gray. When converting to the south gray level, the color f degree of the screen displayed on the liquid crystal display panel is shifted to the blue direction. Therefore, the white balance processing must be performed on the liquid crystal display panel 1 to make the blue The brightness of the diphthin B is relatively lowered to maintain the chromaticity point at a standard value. For example, please refer to FIG. 5, which shows that when the liquid crystal display device is white balanced, the alizarin 11 The white gray scale brightness Gw displayed by 〇 changes from the value Vw to the value Vw+9, the red book element R', the green element G, the blue element B, the second area D, and each The first region L, the displayed gradation brightness grd, gri/, gqd, "Ggl, GBD, GBL, by the value (0), Vrl,), (〇), (Vgl), (〇), • (vBL,) change to the value (16), (Vrl, +26), (16), (Vgl +24), "(1), (Vbl , + 23 卜, blue 昼素B, the second area D, the displayed gradation brightness GBD, converted from the value 〇 to the value 1, occurs in the higher gray level brightness Gw' (value vw, + 9), so that the blue sub-small B, the brightness is reduced relative to other elements to compensate for the shift of the chromaticity point (white balance processing). 8 200842814 However, please refer to Figure 6, white The balancing process causes the turning point C'6 of the blue corresponding curve L6' to deviate from the turning points c, 5, c, 4, resulting in the user's side view angle (relative to the front view 60 degrees) in the gray level interval I. The angle of the display is yellowish, which is commonly known as yellowish, which causes the quality of the kneading surface to decrease. Therefore, how to provide a liquid crystal display device capable of improving the color spot, the liquid crystal display panel and the driving method thereof It is one of the important lessons of the current display industry. [Invention] In view of the above issues, The object of the invention is to provide a liquid crystal display device, a liquid crystal display panel and a driving method thereof, which can reduce the occurrence of color spots on the surface, and the liquid crystal display panel according to the invention is provided for the above purpose. Receiving a plurality of halogen data, wherein any of the halogen data is at least ^----------------------------------------------------------------- Array. Spot Correction: ^ is based on the - first-correspondence relationship and the second correspondence relationship ^ to convert the color: the color sub-tennis and the second color sub-halogen data into a 1-material drive signal and - the second data drive Signal, wherein the first system describes the first color sub-small data, the first '~Lu, ^, 罘贝枓 drive 矾 to the library system' and the second correspondence describes the second color sub-picture vocabulary verb 2;显显(4)和古” corresponds to the relationship between the two and the younger brothers. The denier array has a number of alizarins, and any alizarin has at least — 200842814 the first color sub-allin and one second color sub-allin , 辛和第- more times ^ τ % color sub City younger brother - color sub-pixels, respectively, according to the Department of - the information two data drive signals are driven. In addition, in order to achieve the above object, in accordance with the driving method of the present invention, the liquid crystal display panel panel has a plurality of sounds, and the red crystals have a pixel array, a sub-crystal and a The 1 color binary system has at least one first color, color sub-tendin, and the driving method comprises the following retrieving a plurality of pixel data, wherein any one of the color sub-small data and a first color; = at least has - It should be related to the relationship between the first-color sub-study data = a pair of ^ 〃 〃 - 对应 对应 对应 对应 对应 对应 对应 对应 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色= person... according to the correspondence between the two brothers and the second, the conversion of the second data to the second data driving signal, and the correspondence between the two brothers and the singularity signal, and the correspondence between the first color and the first signal The driver (4) Chu Yi αι brother relationship and the brother two correspondence are different; one name 2L and the younger brother-bean driving signal respectively drive the first color sub-pixel and the second color sub-tendin. In the liquid crystal display device according to the present invention, 1 receives a plurality of halogen materials, wherein any of the pixel data is at least =------------- data. The liquid helium display device comprises a backlight module and a liquid crystal display panel. The liquid crystal display panel is opposite to the backlight module, and has a color spot correction module and an array of pixels. The stain correction module converts the first color sub-small material data and the second color sub-200842814 elementary poor material into a first data driving signal and a second according to the first-corresponding relationship and the first-two correspondence relationship respectively. The data-driven 7 tiger>, the middle-and-one correspondence describes the correspondence between the first color sub-plasma data and the first data driving signal, and the second correspondence describes the second color sub-plasma data and the second data driving signal Corresponding relationship, the first correspondence relationship is different from the second correspondence relationship, the halogen matrix has a plurality of halogens, and any of the halogens has at least a first color sub-tendin and a second color sub-dioxide The one color sub-plasma and the second color sub-prime are driven according to the data driving signal and the second data driving signal, respectively. According to the present invention, a liquid crystal display device, a liquid crystal display panel, and a driving method thereof according to the present invention are based on a first correspondence relationship and a second correspondence relationship different from the first pair j, The color sub-pixel data and the second color sub-pixel data are converted into a first data driving signal and a second data driving signal to respectively drive the first color sub-small element and the second color sub-small element. In other words, the operator can adjust the first-correspondence relationship according to the actual situation and the second corresponding relationship is different, so as to adjust the first-color corresponding curve by 4 liters or downgrade of the first data-driven signal level. The deviation between the turning point and the turning point of the curve corresponding to the second color, thereby reducing the color of the spot ^

The bit is raised to shift the turning point of the blue corresponding curve to the low gray level to reduce the turning point of the corresponding curve of the color matching curve and the turning point of the curve corresponding to other colors.

素素, and the second color sub-small or green sub-data drive signal: the turning point of the Ding curve can also be adjusted according to the second corresponding level 11 200842814 to reduce the level of the data drive signal The other colors move to the high gray level of the turning point of the deer curve to reduce the deviation of the turning point of the corresponding curve of the other color and the turning point of the blue corresponding curve, thereby reducing the generation of the macula. In order to achieve the above object, in another liquid crystal display panel according to the present invention, a plurality of halogen materials are received, and any of the halogen data has at least a first color sub-halogen material. The liquid crystal display panel comprises a driving unit and a halogen array. The driving unit generates a first data driving signal and a second data driving signal according to the first color sub-plasma data; the halogen array has a plurality of pixels, and any of the elements has at least a first color book. Any one of the first color sub-systems has a first region and a first:, the domain 'the/first region and the second region are respectively displayed according to the first data axis and the first poor driving signal In addition, in order to achieve the above object, in accordance with another aspect of the invention, a liquid crystal display panel driving method, wherein the liquid crystal display panel has at least one column, the system has a plurality of pixels, and any one of the frames Any one of the first color sub-pictures has: the 匕 driving method includes the following steps: receiving a plurality of books = shaking 'the _ _ 昼 # 料 料 料 料 料 料 料 料 料 料 料 料 料 料 料 料 料 料 料 料 料- The color sub-small y and - the first - 杳 枓 枓 枓 枓 枓 枓 弟 弟 一 一 一 一 一 一 一 一 一 一 一 一 一 一 一 一 一 一 一 一Brother 4 is no longer 'for the above purpose, according to another liquid crystal display device 12 200842814 of the present invention, which receives a plurality of halogen data, and the basin only has ^ ^ ^ τ any of the halogen data is at least color The 昼素 m day display device system, the 杈 group and a liquid crystal display panel, wherein the liquid sputum is firstly opposite, and has a driving unit::: the plate system and the backlight module are generated according to the -first-color sub-small data : The first array of the driving unit is a data-data 啼.蚩I± 弟 料 驱动 驱动 及 及 及 及 及 及 及 贝 贝 昼 昼 昼 昼 昼 昼 昼 昼 昼 昼 昼 昼 昼 昼 昼 昼 昼 昼 昼 昼 昼 昼 昼 昼 昼 昼 昼The sub-system has a first region and - the color f" the second region has a #垆$__弟-£ domain, wherein the first region and the younger L (four) knife are displayed according to the brother-like axis signal signal-- (4) The second type of liquid crystal display device display panel and its driving method according to the invention, which are driven by the first-data driving t and the younger one driving driving signal respectively. Drive the first field separately: dim or bright to produce the first-color sub-picture Repair domain ;: 1: ㈣❹ turning / turning curve corresponding to the other colors of the "dip deviation, thereby reducing the occurrence of color irregularity. For example, 'Right brother's one color book sound; ^ @ 2 + main first - data drive signal and second capital, in order to reduce the blue corresponding curve, of course, the second deviation of the turning point, and thus reduce the production of green spots of the yellow spot When the sub-small element is a other color element (for example, red sub-tendin), the relative adjustment of the first data driving signal and the turning point of the other color corresponding curve to the high gray s to lower the turning point of the other color corresponding curve correspond to the blue color.曲13 200842814 The deviation of the turning point of the line, thereby reducing the production of the macula. In order to achieve the above object, according to still another liquid crystal display panel of the present invention, the f receives a plurality of halogen data, the _ 昼-昼 资料 data system, at least two 色 色 昼 昼 及 及 and the second color sub Alizarin data. The liquid crystal display includes a halogen matrix and a bias generating unit. The halogen array has: a plurality of halogens, wherein any of the halogens has at least a first color sub- and a second color sub-halogen. The first color sub-system has a first region-and a second region, and the second color sub-system has a third region and a fourth region; the bias generating unit is respectively associated with the first region and the first region The two-region electric power is connected so that the first-sub-pixel data is displayed together with the -first voltage difference between the first-small element (four) of the first region and the first-negative voltage of the second region. And respectively outputting a second color difference between the third region and the fourth region to have a second voltage difference between the third pixel voltage of the second region and the fourth voltage of the fourth region The first data difference is different from the second voltage difference. In addition, in order to achieve the above object, in accordance with another aspect of the present invention, a liquid crystal display panel has at least one halogen array which has a plurality of halogens, and any of the halogens has at least = first color: the halogen and the second color, the first color, the first color, and the second color, the second color, and the second color, and the second color, the second color, and the second color The fourth region 'the driving method of the liquid crystal display panel comprises the following steps: generating a first pixel voltage and a first: pixel voltage from the first region and the second region to jointly display the first color sub-halogen data, wherein - There is a first voltage difference between the halogen voltage and the second halogen battery; the third region 14 200842814 generates the second third halogen battery and the fourth pixel is repeated. And the fourth Dan Jing Electric has a difference between the first thunder and the difference. The Mi voltage difference system and the second one, in order to achieve the above purpose, according to the invention, the system receives a plurality of pixel data, and any of the pixel data "" 显显τ二系包括- backlight module and - a liquid crystal display panel, wherein the liquid = generating unit. The halogen array has a plurality of halogens, any -1 has a first color sub-halogen and - a second color sub-book, the first system has a first region and - Two regions, "two; Ί, 糸 have - second region and - fourth region; bias generation single: two: the first region and the second region are electrically connected, so that the first region m The second region - the second pixel voltage has a second power and a first color sub-pixel data, and = 1, the second region and the fourth region are electrically connected, so that one of the third regions The second voltage sub-halogen data is displayed between the halogen voltage and the fourth region-fourth voltage, wherein the first voltage I and the second voltage difference are different, Still another liquid crystal display device of the present invention is a 丨 , 〜 〜 四 四 四 四 四 四 四 四 四 四 四 四, the panel and its driving method towel, the -f differential pressure system and the second voltage difference and 盥, so according to the difference, the deviation of the turning point of the first color corresponding curve and the turning point of the color corresponding curve can be reduced, thereby reducing the stain The production of 15 200842814 students. For example, if the first color is a blue scorpion, and the second color sucrose is other color sucrose (such as red succulent or green scorpion) Then, the first voltage difference can be made smaller than the second voltage difference to move the turning point of the blue corresponding curve to the low gray level to reduce the deviation of the turning point of the blue corresponding curve from the turning point of the other color corresponding curve, thereby reducing the generation of the macula. [Embodiment] Hereinafter, a liquid crystal display device, a liquid crystal display panel, and a driving method thereof according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings. [First Embodiment] Please refer to FIG. The liquid crystal display panel 2 of the first embodiment of the present invention receives a plurality of halogen data d2〇, wherein any of the halogen data has at least a first-color sub-small material data D21 and a second color sub-smectin The material D22, the liquid crystal display panel 2 comprises a color spot correction module 21 and a pixel array 22. The color spot 杈 positive modulo 21 is respectively based on a first correspondence relationship Ri and a second correspondence relationship R2 to The color sub-plasma data & and the second color: the halogen data D22 is converted into a first data driving signal ~ and a second data driving signal s22. wherein, the first correspondence corresponds to the first color sub-element Corresponding relationship between the data D21 and the first data driving signal S21, and the second correspondence relationship, R2 is a description of the correspondence between the second color sub-plasma data D 2 2 and the second data driving minus s22, and the first pair is dependent on Ri Corresponding to the second 16 200842814, the R2 system is different. The halogen array 22 has a plurality of halogen P2, and any halogen P has at least - the first color sub-purin P21 & - the second color sub-element ^ ^ The ith i-color sub-Pseudo-P2i and the second-color sub-pixels & are driven according to the dynamite-driven driving signal S21 and the second data driving signal & In other words, the operator can adjust the first-correspondence relationship R according to the actual situation to adjust the turning point of the first-color corresponding curve and the turning point of the second color corresponding curve by raising or lowering the level of the data-driven signal S21. The deviation 'in turn reduces the generation of stains. Now, for example, if the first color sub-halogen Pn is blue sub-halogen, and the second color sub-purin P22 is other color sub-halogen (for example, red sub-halogen or green sub-halogen), then according to the - Correspondence relationship R1 raises the level of the first data drive signal S21 and moves the turning point of the blue corresponding curve to the low gray level to reduce the deviation of the turning point of the corresponding curve of the stored color from the turning point of the corresponding curve of the other color, and further Reduce the production of macula. \D Of course, according to the second correspondence R2, the level of the second data driving signal s22 can be lowered to make the turning point of the other color corresponding curve to the high gray P white to reduce the turning point of the other color corresponding curve. The deviation of the blue curve from the 靡 curve to 2 points, which in turn reduces the production of the macula. ~ In the embodiment, the 昼-昼素资料 d2〇 has a third color sub-small material #料 D23 ′ and any—the alizarin P2Q has a third color sub-alliner P"23. The color spot correction mode and the group 21 are respectively converted according to a third correspondence r3 to convert the first-color sub-degraded material & to a third data-driven signal core 3 to drive the third color sub-small element p23. The third correspondence & can be less than 17 200842814 and is different from the first correspondence & and the second correspondence r2. For example, the third correspondence r3 is different from the first correspondence relationship and the second correspondence R2, respectively, or the third correspondence R3 is different from the first correspondence Ri and is the same as the second correspondence or the third correspondence The relationship R3 is the same as the first corresponding relationship and different from the second corresponding relationship R2. In addition, the first color sub-alliner P21, the second color sub-halogen P22, and the third color sub-pixel P23 may be designed according to the conventional low color-shifting technique. In other words, any of the color sub-pixels P21, P22, and P23 has at least a first area and a second area, wherein the first area and the second area are respectively represented by a bright area and a dark area. Do not repeat them. An example will be described below to explain the liquid crystal display panel 2 of the first embodiment of the present invention. Referring to FIG. 8, the stain correction module 21 includes a first gamma voltage generating unit 211, a second gamma voltage generating unit 212, and a driving unit 213. The driving unit 213 is electrically connected to the first gamma voltage generating unit 211 and the second gamma voltage generating unit 212 to provide a first group reference voltage V and a second group reference voltage different from the first group reference voltage Vi. • V2. The first set of reference voltages 乂1 can be designed according to the mutual resistance of the resistor string of the driving unit 213, the resistor string of the first gamma voltage generating unit 211 or the input voltage of the first gamma voltage generating unit 211. Similarly, the second set of reference voltage V2 can be designed according to the resistance string of the driving unit 213, the resistance string of the second gamma voltage generating unit 212 or the input voltage of the second gamma voltage generating unit 212. 18 200842814 Yuan 213 is based on 苐-色子昼素, ^考^% obtained with the first color sub-pixel ^ second color sub-book line motion signal 1 and is based on the two-color book; capital: Γ γ! 2, the second reference money corresponding to the first 枓 (4) is obtained as the first: 目:?, S22. At this time, it can be adjusted according to the actual situation (for example, the device has read no yellow spots, or the human eye has accepted) - The color of the group color test voltage V2 is different, and the money corresponds to the first data of the first data source driving signal S21. The turning point of the first color corresponding curve and the second color pair, The deviation of the turning point, thereby reducing the generation of the stain. Another example is given to illustrate the liquid crystal display panel 2 of the first embodiment of the present invention. Referring to FIG. 9, the difference is the color spot correction module. The 21 series includes a correction unit 214 and a drive The correcting unit 214 can correct the first color sub-small data D21 to the first-color sub-tend correction data DZ1' according to a comparison table (1〇〇k_uptable), and the driving unit is based on the first color sub- The morphological correction data 〇^ is generated to generate the first poor driving driving signal Su to drive the first color sub-small element p2i. In other words, the change of the level of the first data driving signal Sn can be corrected according to the first color sub-small material. And adjusting to correct the deviation of the turning point of the first color corresponding curve and the turning point of the corresponding curve of the second color, thereby reducing the generation of the color spot. 19 200842814 For example, if the first color sub-small element P21 is a blue sub-salmon, and the When the two-color sub-purin p22 is a other color sub-small element, the correcting unit 214 increases the gray-scale value of the first color=pixel data D21 as the first color sub-::: positive capital: D21' grayscale value And the driving unit 215 corrects the data of the first data driving signal S21 according to the first-color sub-purity correction data of the same fire level value, and corrects the corresponding curve of the turning point of the blue corresponding curve. Turn off deviation, And reducing the generation of the macula., -, and for example, if the first-color sub-pixel p2i is good for other colors, and: - the color sub-alloy h is blue, the correction unit 214 will - the gray scale value of the color sub-crystal data D21 is decreased as the gray scale value of the first color correction data D21', and the driving unit 215 is based on the first color sub-pixel correction data D21 of the lower gray scale value In order to reduce the deviation of the turning point of the other corresponding curve and the turning point of the blue corresponding curve, the deviation of the turning point of the other corresponding curve is reduced, thereby reducing the generation of the macula. Of course, the correcting unit can be made according to actual needs. At the same time, the first, the color sub-small element data and the second color sub-pixel data are corrected to a first color sub-album correction data and a second color sub-pixel correction data 'and the drive is based on the first-color sub-color The morphological correction data and the second color sub-segment•= data are used to generate the first data drive signal and the second data drive (four) number (not shown). The following is an example to illustrate the liquid crystal display panel 2 of the first embodiment of the present invention. Referring to FIG. 10, the first color sub-allindin P21 has a first _ p211m domain p212; the second color sub-purin P22 has 20 200842814 a second region P221 and a fourth region P222; the third color The sub-Pseudo-Pm system has a fifth region P231 and a sixth region p232, wherein the color sub-halogens Pn, Pu, and P23 are exemplified by blue scorpion, red scorpion, and green scorpion. In addition, the design of the stain correction module 21 can be designed according to FIG. 8 or FIG. 9 and will not be described herein. The stain correction module 21 can drive the first region ρ2ΐ, the second region P212, the third region P22i, the fourth region P222, and the fifth according to the corresponding relationships Ru, r12, r% R2i, R22, R31, and r32, respectively. The area P231 and the sixth area P232 display the gradation of each gradation. For example, please refer to FIG. 11 , which shows the white gray scale brightness Gw displayed by the pixel P2 ,, and changes from the value Vw to the value Vw, + 9 , the gradation brightness Grd displayed in each area p211 , , Grl, Gqd, ,, Gbl, from the values (0), (vw), (0), (vGL,), (o), (VBL, +9) t to the value (16), (vrl , +26), (16), (vgl, + (Vbl, + 31). u

Since the second region of the color sub-Pseudo-Phase P21 (blue sub-halogen) has a color, GBD, from the value 0 to the value " occurs Vw, + 5 gray-scale brightness Gw ' is better than Figure 5 , the second area D, the displayed gradation brightness ~, from the value Q- to the value (four) is born in the value VW, + 9 gray level brightness GW, to come low. Moreover, the first region p of the color scorpion P21 (blue scorpion) and the gradation brightness GBL are higher than the blue sapphire B: 1 丄 second shown in FIG.

The gradation brightness G displayed in the field D' is not bl'' to correct the deviation of the turning point of the first color (blue) pair 21 200842814 from the turning point of the second color (other colors), thereby reducing the generation of the stain. It is worth mentioning that, due to the above design, the chromaticity of the chromaticity of the liquid crystal display panel 2 is displayed in a blue color, which can be matched with a backlight module, which provides a yellowish backlight to the liquid crystal display panel. In order to compensate for the deviation of the chromaticity point of the picture, the yellowish backlight can be achieved by changing the grading powder in the backlight module, and the health can also be described as a material. In addition, the first regions p2n, p22i, and p23i of FIG. 10 and the second regions ^u, P2u, and P232 are corresponding to each other, and the areas are equal. Of course, the :- region P211, P221, P231 and the second region Ρ212 ”" may have different designs depending on the situation. For example, please refer to the first region ρ2ιι, ρ22ι, ρ23ι and The areas of the second regions ρ2 ΐ 2, ρ 222, and Ρ 232 are not equal. The eye is shown in FIG. 13 and shows a driving method of the liquid crystal display panel of the first embodiment of the present invention, wherein the liquid crystal display panel has at least a pixel array. , the system has a plurality of halogens, and any of the halogens to the ^ 2 - the -I 贞 昼 及 and the second color 昼 ,, the driving method comprises the steps S100 S S130. Step S100 receives a plurality of halogen data, and the material has at least a first color sub-small data and prime data. Step SU0 is based on a first correspondence to the first color. ^ The data is converted into a - data-driven signal, wherein the first correspondence: 22 200842814 describes the correspondence between the first color sub-plasma data and the first data-driven signal. Step S120 is based on a second correspondence two The chromatographic data is converted into a second data driving signal, wherein the second correspondence describes a correspondence between the second color sub-plasma data and the second data driving signal, and the first correspondence is different from the second correspondence. Step S130 is to drive the first color sub-halogen and the second color sub-element according to the first data driving signal and the second data driving signal respectively. The driving method of the liquid crystal display panel of the present embodiment has been displayed in the liquid crystal display of the first embodiment. In the panel (as shown in FIG. 7 to FIG. 12), the liquid crystal display device according to the first embodiment of the present invention receives a plurality of halogen materials, and any of the halogen materials. The liquid crystal display device comprises a backlight module and a liquid crystal display panel. The liquid crystal display panel is opposite to the backlight module and is provided with a π, a melon μ Month sighs, i has a color correction module and a halogen array. The stain correction module is based on a first -: relationship and - second correspondence to the first color sub-sino data and The color sub-plasma data is converted into a first data driving signal and a first material driving signal, wherein the first correspondence describes a correspondence between the first color sub-competition data and the first-data driving signal, and the second corresponding relationship ς refers to the correspondence between the second color sub-small data and the second data-driven signal' the first-correspondence relationship is different from the second corresponding relationship. The alizarin array is a singular element, and the arbitrarily-characterized system has at least - The color sub-book is a second color sub-small sputum 'the first color sub-salmon and the second color sub-salmon 23 200842814 is driven according to the first poor driving signal and the second data driving signal. The liquid crystal display panel of the liquid crystal display device has been described in detail in the liquid crystal display panel of the first embodiment (as shown in FIG. 7 to FIG. 12), and details are not described herein. It is worth mentioning that the backlight module provides a backlight to the liquid crystal, and the chromaticity value of the light source of the $ light source can be adjusted correspondingly according to the first correspondence and the second corresponding relationship. For example, the first color sub-pixel is a blue sub-din, and the second color sub-element is another color sub-tendin. The color patch correction module adjusts the deviation of the blue corresponding curved turning point from the other color pair turning points according to the first correspondence relationship to adjust the first data driving signal level. At this time, the f-light source of the H module can provide a bias! The backlight is applied to the liquid crystal display panel to correct the chromaticity point of the surface displayed by the liquid crystal display device. [Second Embodiment] A liquid crystal display panel 3 according to a second embodiment of the present invention is shown in Fig. 14 . The liquid crystal display panel 3 receives a plurality of pixel data D3, and any of the pixel data D3 has at least one first color sub-pixel data. The liquid crystal display panel 3 includes a drive unit-pixel array 32. Once the driving unit 31 generates a first data driving signal Ssll and a second data driving signal center according to a first color sub-small data 〇31. The alizarin array 32 has a plurality of alizarin p3Gs, wherein the y, dan Γ 30 system has at least one first color sub-halogen, and any of the first color sub-books 24 200842814 prime Pm has a first-region P311 and a second area p312. The first zone i or P 蚣 卜 311 and the second zone p3U are respectively displayed according to the first data driving signal and the first data driving signal S312, a first color sub-study correction bead material. In other words, The first region p311 and the second region P312 respectively reduce the first color according to the first data driving signal s311 and the second data driving signal s312, respectively, respectively, being dim or bright to jointly represent the first color sub-tend correction data. The deviation between the turning point of the corresponding curve and the turning point of the curve corresponding to other colors, thereby reducing the generation of the stain. For example, if the first color subpixel P31 is a blue sub element, then the first data transcoding number S311 and the data driving signal s312 are appropriately made to move the turning point of the color matching curve to the low gray level. Reduce the deviation of the turning point of the blue corresponding curve with other colors and the turning point of the curve, thereby reducing the generation of the macula. When the first color sub-small P31 is another color element (such as red scorpion or green scorpion), the first data driving signal SM1 and the second data driving signal are appropriately adjusted to make other colors The turning point of the corresponding curve moves to the high gray level to reduce the deviation of the turning point of the corresponding curve of the other color and the turning point of the corresponding curve of the color matching, thereby reducing the generation of the macula. In addition, any element P3 has a second color sub-small p32 and a second color sub-small P33. Any of the second color sub-small p32 has a second region Psn and a fourth region p322, and any of the third color sub-small cells P33 has a fifth region p331 and a sixth region p332. The driving unit 31 can generate two feed driving signals according to the second color sub-data d32 to drive the third region p32i and the fourth region bn, respectively. 25 200842814 Of course, the third color driving technology can also be used to drive the third The area and the fourth area P322 are not described here. Similarly, the driving unit 31 can generate two data driving signals according to the second color sub-data data Du to drive the fifth area and the sixth area P332 respectively. Of course, the fifth region ρ33ι and the sixth region p332 can also be driven according to the conventional low color shift technique, which will not be described here. In addition, the first region p3il, the third region p321, and the fifth region PM! of Fig. 14 correspond to the second region p3i2, the fourth region p322, and the sixth region P332, respectively, and have the same area. Of course, the first region P311, the third region P321, the fifth region Pm, the second region Pm, the fourth region P322, and the sixth region P332 may have different designs depending on actual conditions. For example, referring to Fig. 15, the first region P311, the third region, and the fifth region P3H are not equal in area to the second region P312, the fourth region P322, and the sixth region p332, respectively. An example will be given below to explain the liquid crystal display panel 3 of the second embodiment of the present invention. Referring to FIG. 16, any of the first regions has a first switch element SM11, a second switch element, a first liquid crystal capacitor cl1111, a first liquid crystal capacitor cl1112, and a first storage capacitor ct. And a first storage capacitor CT3n2. In addition, any second region pgi2 has a first switching element Ssm, a second switching element core (2), a first liquid crystal capacitor cl3121, a second liquid crystal capacitor CL3i22, a first storage capacitor CT 3112 and a second Store capacitor CT3122. The first end of the first switching element Smu and the first liquid crystal capacitor 26 200842814 cl3 (1) - the end and the first storage capacitor (3) (1) - the end of the two switching elements, the - the end of the second liquid crystal capacitor%" And the second storage capacitor CT3u2 one of the miscellaneous connections, the first liquid crystal external 1 and the second liquid crystal capacitor CL · 3112 one end of the electrical connection:, the younger - switching element a second end and the second open: one brother Two ends are electrically connected. The first end of the first dynasty 'the first switching element s is electrically connected to the end of the first liquid crystal 3121 and one end of the first storage capacitor CT3m, and the other one of the first switching element Du Q ^ electric 丨 卜 3 3122 One end is electrically connected to one end of the second liquid crystal capacitor CL· 3122 and the second one stored in the Leliu storage CT3122, and the first electric: one end of the MU and one end of the second liquid crystal capacitor are electrically connected. The second end of one of the switching elements % and the second end of the second \122 are electrically connected. D(1)Π”? The crystal display panel 3 further includes a plurality of data lines, a storage 3 storage device, and a plurality of scanning lines S3(1) to S3(i+1) and a plurality of segments/(j+2), wherein the 'data line D3(1) Are you in and '70 s:1? 3121 - the third end and the second switching element 3112 3122 the second end of the electrical connection. The scan line S3(i) is connected to the first storage port and the scanning line is connected to the second storage terminal b3(1) of the second switch and the second switching element S3m. The other end of the storage electrode ^3U1 is electrically connected, and the other end of the storage diode line B3 (j + 1) and the second storage electric storage capacitor CT3121 is electrically: the other and the reverse, and the storage electrode line 27 200842814 B3(j + 2)^ is electrically connected to the second storage capacitor. The first switching element S3111 and the second switching element & 3112 of the s-Pm are simultaneously guided by f. ς ς ( (turn οη) 4, the first data drive ~= 糸, and the data line D3 (1) and the first liquid crystal capacitor cl, and the liquid crystal capacitor CLm2, together to produce the first - 昼 电 电"-The first opening of the area P3U: When the component is turned off (t...ff), the first solid and the first two are connected to the first through the storage electrode, the line B3(1) and the storage electrode...the first storage of 3ιι The capacitor and the second storage Ray _ valley CAm. However, since the first liquid crystal capacitor CT ^ ^ valley L3L 3111 of the first region P311 is electrically connected to one of the second liquid crystal capacitors CL3m, the _. —_ · The first storage of electricity in the area of the PSU, the first storage of electricity, the CT 3Π1, the first liquid crystal emperor, the influence of the divination day CL 3111 and the younger brother of the first area P3III - storage Lei i PT1 AL1 ΛτΜ

@仔奋奋 CT 3m on the second LCD capacitor CX

The influence of Ml2 is balanced with each other (+ Λ v fishing Λ ^ 饵 1 1 is balanced with each other), so that the first de a + ^ 弟 日 daily capacitance cl3111 and the second liquid crystal capacitance Chn2 of the first region P3n have the first 共同Prime voltage. Similarly, the younger brother-zone? When the first switching element S3121 and the second switching element S3122 of 312 are simultaneously turned on, the second data driving signal s312 is turned into the first liquid crystal of the second region P 3 i 2 via the lean line D 3 (1 + 1 ). The capacitor CL3121 and the second liquid crystal capacitor CL3122 jointly generate a second pixel voltage, and when the second-switcher s3122 of the second-region element is turned off, the two bias signals _Λν, +Δν Via storage electrode, line B3 (j+1) and storage electrode line 28 200842814

/ k B3 (^+2) and the first storage capacitor dm and f of the second region p(1) are stored in the storage capacitor CT3122. However, since one end of the liquid crystal capacitor CL3121 of the second region p312 is connected to the second liquid crystal capacitor CL3122, the influence of the first storage capacitor CT=21 of the second region p312 on the first liquid crystal capacitor CL3121. The first storage capacitor CT3m of the second region p312 is balanced with respect to the second liquid crystal capacitor CL 3122 (+ Δ v and _ Δ V are balanced with each other), so that the first liquid crystal capacitor CL 3112 of the second region 2 312 and The second liquid crystal capacitor cl3122 has the second halogen voltage. At this time, the first region P311 and the second region Pm2 respectively display the first color sub-tend correction data according to the first pixel voltage and the second pixel voltage. In the case of GAN + λ, any of the third regions p32i has a switch 7L member S321l, a liquid crystal capacitor CL, and a storage capacitor H211. "Ren-fourth region & at least one switching element s3221, day of the day, each CL322" and a storage capacitor CT. - One of the first end of the switch element S3211 and the liquid end and storage capacitor One of the CT3211 is electrically connected, and the end of the switch element 3221 is connected to the liquid crystal capacitor CL3221, one of the CT3221, 浐+阽蝻π 3, and stored. The electric pen s3211, s The scanning line S3(1) is connected to the switching element and the faulty capacitor (4). The storage electrode line is electrically far from the other end of the galvanic grid πη. The B3(j + 1) system and the storage capacitor cT: the sub-pole line- The rb 3221 is electrically connected. The second section P32 and the fourth zone drive the S32 and the bias signal +Δν according to the same data to display the second color sub-study data. Of course, the third area Ρ32! and the fourth area Ρ322 can also be designed as shown in the first area PM1 and the second area ρ^2, and are not described here. Furthermore, in the present embodiment, the switching elements S3111, S3112, S3121, s3122, S32U, and s3221 are a thin film transist 〇r TFT, which is the first region p祀 and the first The two regions 'respectively, the younger-lean-driven driving signal s311 and the second data-driven signal S312 are respectively dim or bright to indicate the first-color sub-alloy correction data, so can be the turning point of the low-color corresponding curve The deviation from the turning point of the curve corresponding to other colors. In addition, the following description will be further described for the first liquid crystal capacitor cL· 舆 the second liquid crystal capacitor CL3112, CL 五 丄 3112 LL3122. Please come to Zhaotu π and Figure 18 at the same time, this month j is only... 尨八wa ^ . In this example, a common electrode CP30 is connected with a single element electrode ep31 and one is checked, Assume. Among them, the first-region p-the first liquid crystal capacitor, the night 曰V two; the through electrode CP3. It is defined with the halogen electrode EP31; the second = electric valley is defined by the common electrode CP3Q and the halogen electrode EP32. Another 'any first region ρ φ 曰 AL , 1 , Ml has a first electrical extension L311 One of the lanthanum is connected to the first element electrode EP31), and the other end of the other end 3111 (also referred to as 昼糸 is connected to the second liquid crystal capacitor CL3112 (also the core electrode ep32), and the line S3(1) The system has a first-year packet extension "with scanning, having parasitic capacitance. Similarly, the first liquid crystal capacitor and the second liquid crystal capacitor of any second region 30 200842814 are also like the first liquid crystal capacitor of the first region p311. The cl3111 and the second liquid crystal capacitor cl3112 are not described here. In addition, as shown in FIGS. 16 and 18, the liquid crystal capacitor CL3211 of the third region P321 is defined by the common electrode CP30 and a halogen electrode EP33.

I is formed, and the common electrode CP30 and the halogen electrode EP33 are opposed to each other through the liquid crystal layer LC30. Similarly, the liquid crystal capacitor cl3221 of the fourth region P322 is defined by the common electrode CP30 and the monolithic electrode EP33, and the common electrode CP30 and the halogen electrode EP34 are opposed to each other through the liquid crystal layer LC3. Where is the third area P321 or the fourth area? 322 may further have a second electrical extension l321, wherein the third region p321 has a second electrical extension l321 as an example. One end of the second electrical extension portion 321 is connected to one end of the liquid crystal capacitor cl3211 (the pixel electrode EP33) and has a second parasitic capacitance between the scanning line S3(i). The capacitance value of the first parasitic capacitance is substantially the same as the capacitance value of the second parasitic capacitance, so that the feed through effect of the first color sub-halogen P31 is the same as the feed through effect of the second color sub-halogen P32 To avoid the occurrence of color shift. Of course, the third phase P321 and the fourth region P322 can have the second electrical extension at the same time according to actual needs, thereby avoiding the occurrence of color shift. Further, the magnitude of the second parasitic capacitance may actually be determined by the size of the area interleaved between the second electrical extension and the scanning line and the distance between the second electrical extension and the scanning line. Referring to FIG. 19, it shows a driving method of a liquid crystal display panel according to a second embodiment of the present invention, wherein the liquid crystal display panel has at least 31 200842814, and has a pixel array having a plurality of halogens, and any one of them. The primordial system has at least a first color sub-smectin, and any one of the first color sub-small elements has a first region and a second region. The driving method includes steps S200 to S210. Step S200 receives a plurality of pixel data, wherein any of the pixel materials has at least one first color sub-small material. Step S210: generating a first data driving nickname and a second data driving signal according to the first color sub-plasma data to drive the first region and the second region to display a first color sub-purinary correction data. The driving method of the liquid crystal display panel of the present embodiment has been described in detail in the liquid crystal display panel of the second embodiment (as shown in Figs. 14 to 18), and will not be described herein. According to a second embodiment of the present invention, a liquid crystal display device includes a light stop group and a liquid crystal display panel. Wherein, the liquid crystal display device receives a plurality of pixel poor materials, and any of the halogen data has at least one first color sub-tendant poor material. The liquid crystal display panel is opposite to the backlight module and has a - drive = unit and a pixel array. The driving unit is based on the fact that the first color sub-nano-depleted material-first data driving signal and the second data driving signal'·the tracing system have a plurality of elements, and any of the alizarin systems has at least one first- The color sub-synthesis has a "first-region" and a second region, wherein the /-region and the second region are respectively displayed according to the first-data driving signal and the second data driving signal--the color sub-segment correction data. The driving method of the liquid crystal display panel of the present embodiment has been described in detail in the liquid crystal display panel of the second embodiment 32 200842814 (shown in Figs. 14 to 18), and will not be described herein. According to the above invention, the liquid crystal display device, the liquid crystal display surface 2 and the driving method thereof are respectively driven according to the first data driving signal and the second two material driving signals to respectively drive the first region and the second The regions are dimly lit or bright to indicate the first color sub-tend correction data, so as to reduce the deviation of the turning point of the first color corresponding curve from the turning point of the other color corresponding curve, thereby reducing the generation of the color spot. For example, if the first color sub-pixel is a blue sub-pixel, the first data driving signal and the second data driving signal will move the turning point of the blue corresponding curve to the low gray level to reduce the blue corresponding curve. The turning point and other colors correspond to the deviation of the turning point of the curve, thereby reducing the generation of the macula. Of course, if the first color sub-small element is another color element (for example, red sub-albumin or green sub-tendin), the first data driving signal and the second data driving signal may be adjusted to make the other color corresponding to the turning point of the curve. Move to the high gray level to reduce the deviation of the turning point of the corresponding curve of the other color from the turning point of the blue corresponding curve to further reduce the generation of the macula. [THIRD EMBODIMENT] Referring to Fig. 20, a liquid crystal display panel 4 according to a third embodiment of the present invention is shown. The liquid crystal display panel 4 receives a plurality of pixel data 〇4 〇, and any of the 昼 〇 〇 〇 〇 〇 及 及 及 及 及 及 及 及 及 及 及 及 及 及 , , , , , , , , 4 includes a halogen array 41, a bias generating unit 42 and a driving unit 43 〇33 200842814 41^ column 41 has a plurality of pixels ～, 昼-昼素, at least has a ---------- And - the second color sub-study ~, the first scorpion scorpion P41 has - a - region ~ and a second region P412, and the brother - color sub-pixel P42 has - the third region four regions P422 . The voltage is generated by the bias voltage τ 42 and the driving unit 43 is electrically connected to the first region p and the second region p412, so that one of the first region (1) = the voltage and the second region P412 - the second pixel voltage There is a jth room difference to jointly display the first color sub-small material D41, and is electrically connected with the third region p421 and the fourth region p422, so that the third region p is cut, the pixel voltage and the fourth A voltage difference between the fourth pixel voltage of the region p422 has a second electrical hysteresis difference to jointly display the second color sub-plasma data, and a voltage difference thereof is different from the second voltage difference. According to the above description, since the first voltage difference is different from the second voltage difference, the deviation between the turning point of the first color corresponding curve and the turning point of the second color corresponding curve can be reduced according to the difference, for example, if When the color sub-pixel P4i is blue sub-halogen, and the second color sub-purin P42 is other color halogen (for example, red sub-halogen or green sub-halogen), the first-electron difference can be made smaller than The second voltage difference is such that the turning point of the blue corresponding curve moves to the low gray level to reduce the deviation of the turning point of the blue corresponding curve from the turning point of the other color corresponding curve, thereby reducing the generation of the macula. In addition, any book Sudanin negative material D43, and any of the book material data D40 may have a third color sub-P40 and may have a third color sub-small element 34 200842814 P43 ° where 'the third color Zizi P43 is the sixth region P432. The bias generating unit το 42 and the driving unit 43 are electrically connected to the fifth region p milk and the sixth region 〜2, so that the fifth region is as a fifth pixel and the sixth region P432 is the sixth 昼There is a third electrical difference between the prime voltages to collectively display the third color sub-tend data Du. The third voltage difference is at least different from the first voltage difference or the second voltage difference. In addition, the first region Ρ41Γ, the third region P42l, and the fifth region P431 of the ® 20 are respectively corresponding to the second region p, the fourth region P422, and the sixth region p432, respectively, and the areas are equal. Of course, the first region hn, the third region, the fifth region & the second region core 2, the fourth region P422, and the sixth region P432 may have different designs depending on actual conditions. For example, referring to FIG. 21, the areas of the first area 匕, the second area P42!, and the fifth area P4M are not equal to the areas of the second area, the fourth area P422, and the sixth area Pa2, respectively. A liquid crystal display panel 4 according to a third embodiment of the present invention will be described below. Referring to FIG. 22, any of the first region hn, any second region 412, any second region P42! The fourth region Pa2 has at least one switching element S411, S412, S421, S422, a liquid crystal capacitor CL411, CL..., CL421, CL422 and a storage capacitor CT411, CT412, CT421, CT422. Switching elements Sd, Sm, S42! The first end of one of the S422s is electrically connected to one end of the liquid crystal cells CL411, CL412, CL42I, CL422 and the storage capacitors CT411, CT412, CT421, CT422, and the second end of the switching element 35 200842814 and the switching element s412 The second end of the S422 is electrically connected. Further, the liquid crystal display panel 4 further includes a plurality of data lines D4(1)D4(i+1), at least one scanning line center (1), and a plurality of storage electrode lines I(1) to Bj+1). Among them, the data line D4 (1) and the switching elements S411, S The second end is electrically connected, and the data and line D4(i+1) are electrically connected to the third end of the switching elements S421 and S422. The scanning line S4(1) is connected to the switching elements S411, s412, s421, s422. The second end is electrically connected. The storage electrode and the line I(1) are electrically connected to the storage capacitors CL and π. The storage electrode and the line B4 (j + 1) are electrically connected to the other ends of the storage capacitors CTm and CT422. When the switching elements S4H and S4 of the first region p411 and the second region ?412 are turned on, the first and the material driving signals Sq generated by the driving circuit (not shown) are via the data line D4(1). Inputting the liquid crystal capacitors CLm and CLm of the first region and the second region ρ〇2, the liquid B solar cells CL4U, CL4U generate a first original pixel voltage and a first U pixel voltage. The first region P411 and When the switching elements S4U, S412 of the second region P412 are turned off, the bias signals + ΔV, _ Δ V generated by the bias generating unit (not shown) are via the storage electrode lines B4(j), B4 ( j + 1) and input storage capacitors CT4U, CTw, first raw pixel voltage of liquid tantalum capacitor and liquid crystal And the second raw voltage of the second 12 and a second raw halogen voltage adjustment, and the voltage of the first element and the second element of the voltage. Similarly, when the switching elements 36 200842814 bn and S422 of the third region P42i and the fourth region p422 are turned on, the driving circuit (not shown) generates the second data driving signal via the data. The line inputs the liquid crystal capacitors cL42i, cl422 of the third region Poi and the fourth region Pc2, so that the liquid crystal capacitors CL42i, CL422 generate a third original pixel voltage and a fourth source pixel voltage. When the third region p is similar to the switching elements Sm, S422 of the fourth region P422, the bias signal + ΔV, _Δ V system generated by the bias generating unit (not shown) is stored. The electrode lines B4(1) and B4(j+1) are respectively input to the storage capacitor f CTwrCTc2, and the third original pixel voltage of the liquid crystal capacitor cLm and the fourth original pixel voltage of the liquid crystal capacitor CL422 are adjusted to the third pixel voltage and the first Tetracycline voltage. Wherein, the third voltage difference between the third pixel voltage and the fourth pixel voltage is different, and the first voltage difference is different from the first: voltage difference. In this embodiment, the different first voltage difference and the second voltage difference are achieved by the storage capacitors CT411, CT412 & CT422 having different capacitance values. For example, if the first color sub-small element P41 (the first region P411 and the second region P412) is a blue sub-halogen, and the second color sub-small element p42 (the third region P4^ and the fourth region P422) is other When the color element (for example, red scorpion or green scorpion), the storage capacitors CT411 and CT412 are smaller than the storage grids CTd and CT422, so that the first voltage difference is smaller than the second voltage difference, and the blue color is made. The turning point of the corresponding curve moves to the low gray level to reduce the deviation of the turning point of the blue corresponding curve from the turning point of the corresponding curve of other colors, thereby reducing the generation of the macula. In addition, the different first voltage difference and the second voltage difference can also be achieved by the liquid crystal capacitors CL4u, ek having different capacitance values. Of course, it is also possible to directly input the bias signals of different levels to the first region m f three regions and the fourth region, so that the first voltage difference is different from the second voltage difference. It is worthwhile to mention that the liquid crystal capacitor is defined by a common electrode and a germanium electrode, and the common electrode and the halogen electrode are opposed to each other through the liquid crystal layer. Therefore, the size of the liquid crystal capacitor can be determined by the size of the area between the pixel electrode and the common electrode, or the distance between the pixel electrode and the common electrode f. In addition, the storage capacitor is defined by a storage electrode and a halogen electrode. Therefore, the size of the storage capacitor can actually be the size of the area between the storage electrode and the halogen electrode, or the storage electrode and the halogen electrode. The distance between them is determined. Referring to FIG. 23, a driving method of a liquid crystal display panel according to a third embodiment of the present invention is shown, wherein the liquid crystal display panel has at least one pixel array having a plurality of halogens, and any of the halogens has at least one a first color sub-small element and a second color sub-small element, the first color sub-pixel system has a first region and a second region, and the second color sub-small system has a --third region and A fourth region, the driving method of the liquid crystal display panel includes steps S300 to S310. Step S300: generating a first pixel voltage and a second pixel voltage from the first region and the second region to jointly display the first color sub-book data, wherein the first pixel voltage and the second pixel voltage are between Has a first voltage difference. 38 200842814 3 Step S31G generates a third pixel voltage and a fourth pixel voltage from the third region and the fourth region to jointly display the second color sub-sufficiency, and, wherein, the third pixel voltage and the third There is a voltage difference between the four halogen electric houses, and the first voltage difference is different from the second voltage difference. The driving method of the liquid crystal display panel of the present embodiment has been described in detail in the liquid crystal display panel of the second embodiment (as shown in FIG. 2G to FIG. 22), and will not be described herein. A liquid crystal display device according to a third embodiment of the present invention, which receives a plurality of pixel data, wherein any of the halogen data has at least a first color sub-denier material and a second color sub-crystal material, The display device includes a light module and a liquid crystal display panel. The liquid crystal display panel is opposite to the backlight module, and has a halogen array and a biasing unit. The halogen array has a plurality of halogens, wherein any of the halogens has at least a first color subpixel and an H color subpixel. The first-color sub-small system is: a first-region and a second region, and the second-color sub-system has: a second, a domain, and a fourth region. The bias generating unit is electrically connected to the first region=the second region respectively to have a first voltage difference between the first pixel voltage of the first region and the second pixel voltage of the second region. The first color sub-halogen data is displayed, and is electrically connected to the third region and the fourth region, respectively, such that the third region - the third pixel voltage and the fourth region is between the fourth pixel voltage There is a second voltage difference and the same color is displayed - the second color sub-pixel data. The first-voltage difference is different. The driving method of the liquid crystal display panel of the present embodiment has been described in detail in the liquid crystal display panel of the third embodiment 39 200842814 (as shown in FIG. 20 to FIG. 22), and details are not described herein. In summary, a liquid crystal display device, a liquid crystal display panel, and a driving method thereof according to the present invention are based on a first correspondence relationship and a second correspondence relationship different from the first correspondence relationship to draw the first color sub-picture The data and the second color sub-plasma data are converted into a first data driving signal and a second data driving 5 domain' to drive the first color sub-halogen and the second color sub-halogen. In other words, the operator can adjust the first-correspondence relationship according to the actual situation and the second corresponding relationship is different to adjust the level of the first data-driven signal to increase or decrease to correct the turning point and the second color of the first-color corresponding curve. Corresponding to the deviation of the turning point of the curve, thereby reducing the generation of stains. For example, if the first color sub-salm is work + main - one bargain; and 儿,, 儿 顋 k k 为 为 为 为 为 为 为 为 为 为 为 为 为 为 为 , , , , , , , Differentiated 'to increase the level of the first data-driven signal: the turning point of the color corresponding curve and the curve of the other color corresponding to the curve: poor; thereby reducing the generation of the macula. Of course, it is also possible to adjust the deviation of the (four)'' his color-corresponding curve and the blue corresponding to the 'pinch point' of the second pair of curves, thereby reducing the generation of the macula. In addition, because another liquid crystal display device according to the present invention is based on the first-data driving, the first region and the second region are driven by the gas to generate the brother-color sub-alloy correction data. In order to reduce the deviation of the turning point of the corresponding curve of the first color from the curve of the other color = the deviation of 200842814, thereby reducing the generation of the stain. For example, if the first color sub-small element is a blue sub-small element, the first data driving signal and the second data driving signal are adjusted so that the second area starts to be raised from the dark state to the bright state. Decreasing the deviation of the turning point of the blue corresponding curve from the turning point of the corresponding curve of the other color, thereby reducing the generation of the macula. Furthermore, the 'first voltage' in the liquid crystal display device, the liquid crystal display panel and the driving method thereof according to the present invention The difference between the difference and the second _ difference, r heart can reduce the deviation of the turning point of the first-color corresponding curve and the turning point of the color-corresponding curve according to the difference, thereby reducing the generation of the stain. (4) Those who are secret-minded. Any equivalents or changes that have not been removed from the spirit and scope of the company shall be included in the scope of the patent application attached. [Simplified description of the schema] Figure 1 is a non-intentional A conventional liquid crystal display panel is shown; FIG. 2 is a schematic diagram showing a characteristic curve of gray scale versus light transmittance of the liquid crystal display panel of FIG. 1; FIG. 3 is a schematic view showing another conventional one. Crystal display panel; ^-schematic diagram showing the characteristic curve of the gray scale versus the first tooth permeability of the liquid crystal display panel in Fig. 2; - sound map 2 = schematic diagram showing the white gray scale displayed by the alizarin: the parentalization of the second The change of the gradation brightness displayed by each of the first regions of the red sputum, the green sputum I, and the blue scorpion is 41 200842814; FIG. 6 is a non-thinking view showing the white balance of the liquid crystal display panel in FIG. The characteristic curve of the gray scale on the light transmittance after the processing; FIG. 7 to FIG. 1 is a liquid crystal display panel of the first embodiment of the present invention; FIG. 11 is a schematic view The relationship between the change of the white gray scale brightness displayed by the halogen element and the color tone brightness displayed by each area; - Figure 12 is a schematic view showing the liquid crystal display panel of the first embodiment of the present invention; - Figure 13 is - a flow chart showing a driving method of a liquid crystal display panel according to a first embodiment of the present invention; FIGS. 14 to 18 are schematic views showing a liquid crystal display panel according to a second embodiment of the present invention; and FIG. 19 is a flow chart showing the present invention Liquid crystal display panel of the second embodiment FIG. 20 to FIG. 22 are schematic views showing a liquid crystal display panel according to a third embodiment of the present invention; and FIG. 23 is a flow chart showing a driving method of the liquid crystal display panel according to the third embodiment of the present invention. : 1, 1 ', 2, 3, 4: liquid crystal display panel 11 : halogen array 42 200842814 110 : halogen 12 : drive unit 21 : stain correction module 211 : first gamma voltage generating unit 212 : second gamma Voltage generating unit 213 ··Drive unit ^ 214 : Correction unit • 215, 31, 43: Drive unit C 22, 32, 41: Alizardin array 歹 ij 42 : Bias generation unit B, B,: Blue element B3 (1) ~B3(j + 2): storage electrode line B4(j)~B4(j + 1): storage electrode line C'4, C'5, C'6: turning point CL411, CL412, CL421, CL422 ·Liquid crystal capacitor CL3111 , CL·3111. Brother LCD capacitor CL3112, CL 3122·Dimensional liquid crystal capacitor CL3211, CL322I: Liquid crystal capacitor • CT3211, CT3221, CT411, CT412, CT421, CT422: storage capacitor CT3111, CT312i ··The first storage capacitor CT3112 , CT3122: second storage capacitor CP3〇: common electrode D,: second Domain D20, D30, D40 · Alizarin data 43 200842814 D21, D31, D41: The first color sub-plasma data D22, D32, D42: The second color sub-plasma data D23, D33, D43: The third color sub-pixel Data D2r: First color sub-album correction data D3(i)~D3(i + 1): data line D4(i)~D4(i+1): data line • ep31, EP32, EP33, EP34: 昼素Electrode • G, G,: Green Alizarin Gw, · Grayscale

Grd,, GRL, Ggd, · · color gradation

Ggl, Gbd, Gbl,: gradation brightness I: gray-scale interval L311: first electrical extension L32i: second electrical extension LC30 · liquid crystal layer LI, L4, L4': red corresponding curve " L2 , L5, L5,: Green corresponding curve • L3, L6, L6,: Blue corresponding curve • U: First area P20, P30, P40: Alizarin P21, P31, P41 * First color sub-small element P22, P32 , P42 · Second color sub-alliner P23, P33, P43 · · Third color sub-alliner P211, P311, P411: First * area 44 200842814 ? 212, P312, P412: second area ? 221, P321, P421 : third region ^222, P322, P422 · fourth region ^231, P331, P431: fifth region ? 232, P332, P432 · · sixth region R, R, : red halogen Ri: first - correspondence Rll, Rl2: correspondence R2 · second correspondence R21, ^22: correspondence R3 · third-correspondence R31, ruler 32: correspondence S21 · first - poor material drive signal S22 · S23: the first; L data drive signal ^ 311 : the first data drive signal S312 : No., two poor material drive signal S3in > S 3121 : first switching element • S3112 , S : 3122 · · second switching element ^ 3211 , S 3221 : switching element S3 ( i ) ~ S3 (i + Ι): Scanning line S4(i) • Scanning line S 41 · First, a data driving signal S42: Second, second grazing drive signal 45 200842814 S4II, S4i2, S421, S422: Switching elements S100~S130: steps S200~S210 of driving method Steps of the driving method S300 to S310: Steps of the driving method Vi: The first group of reference voltages v2: the second group of reference voltages + + ΔV, - ΔV: bias signals

46

Claims (1)

200842814 X. Patent application scope: 1. A liquid crystal display panel, which receives a plurality of pixel data, wherein the two-dimensional poor material has at least a first color sub-halogen material and a second color sub-halogen material. The liquid crystal display panel comprises: a color spot correction module, wherein the first color sub-tend material and the second color sub-tend material are converted into a first color relationship and a second corresponding relationship respectively a first data driving signal and a second data driving signal, wherein the first correspondence describes a correspondence between the first color sub-plasma data and the first data driving signal, and the second correspondence describes the second Corresponding relationship between the color sub-halogen data and the second data driving signal, the first correspondence relationship is different from the second correspondence relationship; and the denier array has a plurality of pixels, wherein any of the books is at least Having a first color sub-pixel and a second color sub-element, wherein the first color sub-element and the second color sub-element are respectively driven according to the first data and Two data-driving signal is driven. 2. For the liquid crystal display panel described in item i of the patent application, any of the halogen materials has a third color sub-small material, and any of the books has a second color, the color spot. The calibration module converts the third color sub-decimal data into a third data driving signal to drive the third color sub-tendin according to a third correspondence. The liquid crystal display panel of claim 2, wherein the second correspondence is at least different from the first correspondence or the second correspondence. 4. The liquid crystal display panel of claim 1, wherein the stain correction module comprises: Λ a first gamma voltage generating unit; a second gamma voltage generating unit; and a driving unit Electrically connecting with the first gamma voltage generating unit and the first gamma voltage generating unit to provide a first set of reference voltages and a second set of reference voltages, the first set of reference voltages and the second reference voltage Differentiating, wherein the driving unit obtains, from the first set of reference voltages, a first reference voltage corresponding to the first color sub-tend data as the first data according to the first color sub-halogen data Driving a signal, and obtaining a second reference voltage corresponding to the second color sub-pixel data from the second set of reference voltages as the second data driving signal according to the second color sub-plasma data. The liquid crystal display panel of claim i, wherein the color spot correction module comprises a positive unit, wherein the first color subpixel data is corrected to a color and a color subsimple correction data. And driving the single 7G, the system of the first-color sub-pixel correction data to generate the first data driving signal 48 200842814. 6. The liquid crystal display panel according to claim 5, wherein the correction sheet 7C further corrects the second color sub-halogen data to a second color sub-album correction data, and the driving unit is based on the The second color sub-crystal correction data is used to generate the second data driving signal. The liquid crystal display panel receives a plurality of halogen materials, wherein any of the halogen materials has at least one first color sub-halogen material, and the display panel comprises: -, a moving unit, which is based on the - color The 昼素# material generates a first data driving signal and a second data driving signal; and a pixel array having a plurality of pixels, at least having a -th-color sub-pixel, any first The halogen system has a first area and a second area, the first area And the second area displays a first color sub-crystal modifier according to the first data driving signal and the second data driving signal. The liquid crystal display panel of claim 7, wherein any of the first region and the second region has at least one first switching element: a second switching element, a first liquid crystal capacitor, and The first __ end of the second liquid crystal two-cell H-switch is electrically connected to the end of the first liquid crystal cell. The second terminal is the first terminal and the fourth terminal is 49. The liquid crystal display panel of claim 8, wherein when the first-on-off element of the =I region and the first:-switching element are two or two, the first liquid crystal capacitor of the first region of the 5H and the second The liquid crystal capacitor generates the first pixel voltage jointly according to the first data driving signal, and when the first switching element and the second switching element of the second region are conductive, the second region a liquid crystal capacitor and the second liquid crystal capacitor jointly generate the second pixel voltage according to the first data driving signal of the f°H, and the second region and the second region are respectively determined according to the second pixel voltage and the The second halogen voltage displays the first color sub-album correction material 0, The liquid crystal display panel of claim 8, further comprising at least one scan line respectively connected to the driving unit, the second end of the first switching element, and the second switching element The second end is electrically connected. The liquid crystal display panel of claim 10, wherein any one of the first region and any of the second regions further has a first electrical extension portion, one end of which is connected to the first liquid crystal capacitor The terminal is connected to the terminal of the liquid crystal capacitor, and has a first parasitic capacitance between the first electrical extension 50 200842814 and the scan line. 12. The liquid crystal display panel of claim 5, wherein any one of the elements has a second color sub-small element, wherein any of the second color sub-small elements has a -third area and - The fourth region, any three regions and any fourth region have at least a second switching element and a third liquid crystal capacitor, and the third switching element of the third region: the first end system and the third region One end of the third liquid crystal capacitor is electrically connected to the first end of the third switching element of the fourth region and is electrically connected to the third liquid crystal capacitor of the fourth region: 13. Patent application The liquid crystal display panel of claim 12, wherein the second drawing, the wire system, the second end of the third switching element of the third region, and the third switching element of the fourth region are respectively Two ends are electrically connected. 14. The liquid crystal display panel of claim 13, wherein the third region further has a second electrical extension portion, and one end of the third liquid crystal capacitor is connected to one end of the third region. And with the scan: ϊ between! a second parasitic capacitance, the capacitance of the first parasitic capacitance being substantially the same as the capacitance of the second parasitic capacitance. The liquid crystal display panel of claim 13, wherein the four regions further have a second electrical extension portion, one end of which is connected to 51, 200842814, and the third liquid crystal capacitor of the fourth region The terminal has a second parasitic capacitance between the line and the first parasitic capacitance and the capacitance value of the second parasitic capacitance is substantially the same. a liquid crystal display panel, which receives a plurality of halogen data, wherein the halogen data has at least a -th-color sub-halogen material and a second color sub-crystal material, the liquid crystal display panel comprising: The denier array has a plurality of halogens, and any of the pixels has at least a first color sub element and a second color sub element, the first color subpixel has a first region and a a second region, wherein the second color sub-system has a third region and a fourth region; and a bias generating unit that is sexually coupled to the first region and the second region to enable the A first electric quantity between the first halogen voltage of one of the first regions and the second halogen voltage of the second one of the second regions, the difference: common display of a first color sub-tend data, and respectively, /, respectively The first region and the fourth region are electrically connected such that a second voltage difference between the third pixel voltage of one of the second regions and the fourth pixel voltage of the fourth region is combined to display a second Color sub-pixel data, wherein the first voltage difference is It is different from the second pressure difference. The liquid crystal display panel of claim 16, wherein any of the first region, any second region, any third region, and any of the 52 200842814 fourth regions have at least one liquid crystal capacitor and one storage Capacitor, the liquid crystal capacitor of the first region and the liquid crystal capacitor of the second region are different from the liquid crystal capacitor of the third region and the liquid crystal valley of the fourth region, or the storage of the first region The capacitor and the storage capacitor of the second region are different from the storage capacitor of the third region and the storage capacitor of the fourth region. The liquid crystal display panel of claim 16 is further provided with a blow drive unit that generates a first data drive signal and a first data drive signal. For example, apply for the 18th job of the full-time LCD panel, including & the first series, any - the second area, any third area and any one of the four switches, a liquid crystal capacitor and - health storage\ The switching element of the second domain and the second region of the fourth region is the first time region _ ^ ^ ^ ^ ^ ^ $ and the liquid crystal electric valley of the younger region is based on the data of the younger brother The Sulei pressure two tigers respectively generate an original ε to find the second dioxin voltage, and when the first--", the next 5 hai switch element is non-conducting", the original 查-chaben,戋 戋 。 。 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一 第一200842814 When the switching element of the third region and the fourth region is connected to the '(four) three region and the fourth region of the liquid crystal = $ according to the second data driving signal respectively generates an original third denier voltage and an original a fourth pixel voltage, and when the third region ^ the fourth region of the switching element is non-conductive The original third pixel voltage of the third region and the original fourth pixel voltage of the fourth region are adjusted to the third pixel voltage and the tetracycline voltage. The driving method of the panel, wherein the liquid crystal display panel has at least a halogen matrix, wherein the halogen array has a plurality of halogens, and any of the halogens has at least a first color sub element and a color: The driving method comprises: receiving a plurality of halogen data, wherein any of the halogen data has at least a first color sub-purin data and a second color sub-purin data according to a first correspondence to Converting a color sub-small data into a first data driving signal, wherein the first correspondence describes a correspondence between the first color sub-plasma data and the first data driving signal, according to a second correspondence Converting the second color sub-plasma data into a second data driving signal, wherein the second correspondence relationship describes a correspondence between the second color sub-pixel data and the second data driving signal, The first correspondence is different from the second correspondence; and 54 200842814 drives the first color sub-halogen and the second color sub-halogen respectively according to the first data driving signal and the second data driving signal. The method for driving a liquid crystal display panel according to claim 21, wherein any of the pixel materials further has a third color sub-plasma data, and any of the pixels has a third color sub-small element. The step of the driving method further includes: converting the third color sub-halogen data into the third data driving signal according to the third correspondence; and driving the third color sub-book based on the third data driving signal. The method for driving a liquid crystal display panel according to claim 22, wherein the third correspondence is at least different from the first correspondence or the second correspondence. 24 \ If the application of the liquid crystal display panel driving method described in Item 21, wherein the step of converting the first color sub-material into the first data driving signal according to the first correspondence is as follows The second-child color data is used as the first data driving signal from a first set of reference voltages = corresponding to the first color sub-small data. The method of the liquid crystal display panel of claim 23, wherein the step of converting the second color sub-55 25, 200842814 into the second data driving signal according to the second correspondence is based on The second color sub-halogen data is from a second set of reference voltages: a second reference voltage corresponding to the second color sub-halogen data as the second #-material driving signal, the first_the second group The reference voltages are different. The method of converting the first color sub-enrichment data into the first data driving signal according to the first correspondence relationship includes: Correcting the first color sub-halogen data to a first color sub-purinary correction data; and a generating the first data driving signal according to the first color sub-pixel correction data. The driving method of the liquid crystal display panel of claim 21, wherein the step of converting the second color sub-halogen data into the second data driving signal according to the second correspondence comprises: The data is modified into a second color sub-small correction data; and the second data driving signal is generated according to the second color sub-quality correction data. 28. A liquid crystal display panel driving method, which is applied to a liquid crystal display panel 'The liquid crystal display panel has at least one halogen array, 56 200842814 = retanning: the pixel 'any-picture element has at least - the first color 嚷 /, the middle - - the color sub-small system has a first region and a red region, and the method includes: receiving a pixel data, wherein any of the pixel data has at least a dice color data; and according to the first multi-SA The J data is generated by a first data driving signal = a σ first-lean material driving signal to drive the first area and the area to display a first color sub-small correction data. The driving of the liquid crystal (four) panel of the rhyme: the middle-first region and the second-region of the method have at least a switching element, a second switching element, a first liquid crystal capacitor and a second liquid crystal capacitor, the first a first end of a switching element is electrically connected to one end of the liquid crystal capacitor, and a second end of the second switching element is electrically connected to one end of the second liquid crystal capacitor, the end of the first liquid crystal capacitor And electrically connecting the end of the second liquid crystal capacitor to generate a first data driving signal and a second data driving signal according to the first color sub-plasma data to drive the first region and the second Regional common The step of displaying the first color sub-crystal correction data is: when the first switching element and the second switching element of the first region are turned on, the first liquid crystal capacitor and the second liquid crystal capacitor of the first region Generating the first pixel voltage according to the first data driving signal, and when the first switching element and the second switching element of the second region are the first one of the first region The liquid crystal capacitor and the second liquid crystal capacitor jointly generate a voltage according to the second data driving signal, and the first region and the second region respectively display the first Color sub-pixel correction data. 3〇, a driving method of a liquid crystal display panel, wherein the liquid crystal display panel has at least one pixel array having a plurality of pixels, wherein any one of the pixels has at least one a color sub-salm and a second scorpion 豸 豸 豸 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色 颜色Fourth area, the driver Law include: a. The first region and the second region generate a first pixel voltage and a first pixel voltage to jointly display the first color sub-halogen data, wherein the first pixel voltage and the second pixel voltage are between I has a first voltage difference; and 'generating a third pixel voltage and a fourth pixel voltage from the second region and the fourth region to jointly display the second color sub-halogen data, wherein the third picture There is a second voltage difference between the voltage of the element and the voltage of the fourth element, and the first voltage difference is different from the second voltage difference. 31. The method of driving a liquid crystal display panel according to the patent scope 帛3G, wherein any one of the first region, any of the second regions, any of the third 58 200842814 regions, and any fourth region has at least a liquid crystal capacitor and a storage capacitor, the liquid crystal capacitor of the first region and the liquid crystal capacitor of the second region are different from the liquid crystal capacitor of the third region and the liquid crystal capacitor of the fourth region, or the first The storage capacitor of a region and the storage capacitor of the second region are different from the storage capacitor of the second region and the storage capacitor of the four regions. 32. A liquid crystal display device, comprising: receiving a plurality of halogen data, wherein any of the halogen data has at least a first color sub-plasma data and a second color sub-purin data, the liquid crystal display device comprising: a backlight module; and a liquid crystal display panel, which is opposite to the backlight module, and has a color spot correction module, which is respectively configured according to a first correspondence relationship and a second correspondence relationship The first color sub-plasma data and the second color sub-plasma data are converted into a first data driving signal and a second data driving signal, wherein the first correspondence describes the first color sub-genuine data and the first Corresponding relationship between the data driving signals, and the second correspondence relationship describing the correspondence between the second color sub-plasma data and the second data driving signal, the first correspondence is different from the second correspondence, and The halogen array has a plurality of halogens, and any of the halogens has at least a first color sub-pixel and a second color sub-59 200842814, wherein the first color is And the second color sub-book system is driven according to the first data driving signal and the second data driving signal respectively. The liquid crystal display device of claim 32, wherein any of the halogen materials has a third color sub-plasma data, and any one of the elements has a third color sub-pixel. The color spot correction module converts the third color sub-mechanical data into a third data driving signal to drive the third color sub-study according to a third correspondence. The liquid crystal display device of claim 33, wherein the third correspondence is at least different from the first correspondence or the corresponding relationship. The liquid crystal display device of claim 32, wherein the color spot correction module comprises: 〃 a first gamma voltage generating unit; a second gamma voltage generating unit; and a moving unit, Electrically connecting with the first gamma voltage generating unit and the second gamma voltage generating unit to provide a first set of tea test voltages and a second set of reference voltages, the first set of reference voltages and the second set of reference voltages Differentiating, wherein the driving unit is based on the first color sub-halogen data from the first set of reference voltages taken from 200842814 to be the first color g early gold | Delivering the first data driving signal, and according to the second color service; the second material is obtained from the second group of reference voltages and the second color is once a ^^^~ Drive signal. * 36 f'. 37. The liquid crystal display device according to item 32 of the monthly recording, wherein the color spot correction module includes ··, r -: toast early 兀 'the first color of the line The sub-small data is corrected to a first color sub-small correction data; and the dynamic unit' is based on the first-color sub-quality correction data to generate the first data driving signal. Shen. The liquid crystal display device of claim 36, wherein the correction unit corrects the second color sub-halogen data to the ^ color sub-alliton correction data, and the driving unit is based on the second The dice pixel correction data is used to generate the second data driving signal. The liquid sputum display device receives a plurality of sputum data, and the sputum material has at least a _ _ _ 昼 资料 该 该 该 该 液晶 液晶 液晶 液晶 液晶 液晶 液晶 液晶 液晶 液晶 液晶 液晶 液晶 液晶 液晶 液晶 液晶 液晶 液晶 液晶 液晶 液晶 液晶And a display panel, which is opposite to the backlight module, and has: ~ 61 200842814 a driving unit, which generates a first data driving signal and a second data driving according to a first color sub-plasma data And a pixel array having a plurality of pixels, at least one of the pixels having at least one first color, wherein any of the first colors has a first region and a second And a region, wherein the first region and the second region respectively display a first color sub-crystal correction data according to the first data driving δίΐ and the first driving signal. 39. The liquid crystal display device of claim 38, wherein any one of the first region and any of the second regions has at least a second switching element, a second switching element, a first liquid crystal capacitor, and a a first liquid crystal capacitor, the first end of the first switching element is electrically connected to one end of the first liquid crystal capacitor, and the first end of the second switching element is electrically connected to one end of the second liquid crystal capacitor The first liquid crystal=the valley& is electrically connected to the end of the second liquid crystal capacitor. The liquid crystal display device of claim 39, wherein when the first switching element of the first region and the one piece are turned on, the first region of the liquid crystal display device The liquid crystal capacitor and the δXuandi-liquid crystal capacitor jointly generate the sinusoidal voltage according to the first multiplexer and the thimble driving signal, and when the second first switching element and the second switching element are When the conduction period is 62 200842814, the first liquid crystal capacitor and the second liquid crystal electric valley of the first region jointly generate the first, pixel voltage according to the remote data transmission signal, the first region and the second region The first color sub-pixel correction data is displayed according to the first pixel voltage and the second pixel voltage, respectively. The liquid crystal display device of claim 39, wherein the crystal display panel further comprises at least one scan line electrically connected to the driving unit, wherein the scan line is respectively associated with the first switch device One of the second ends and the second end of the second switching element are electrically connected. The liquid crystal display device of claim 4, wherein any one of the first region and any of the second regions further has a first electrical extension ", one end of which is connected to the first liquid crystal capacitor The other end of the second liquid crystal capacitor is connected to the end, and a first parasitic capacitance is formed between the first electrical extension and the scan line. The liquid crystal display device of claim 42, wherein any one of the pixels has a second color sub-small element, wherein any of the second color sub-pixels has a third region and a fourth region Any of the second regions, and any of the fourth regions has at least a third switching element and a first liquid crystal capacitor, and the first end of the third switching element of the third region is associated with the third region The first end of the third liquid crystal capacitor is connected to the one end of the third liquid crystal capacitor of the fourth region. The liquid crystal display device of claim 43, wherein the j trace is electrically connected to the third end of the third switching element of the third region and the third open end of the fourth region. Currency - 45, such as the liquid crystal display device described in the 44th patent range, wherein the second area has a second electrical extension system, the second + text and moved to the door of the line I: The end of the liquid crystal capacitor ′ has a parasitic capacitance between the scan and the scan, and the value is substantially opposite to the capacitance of the second parasitic capacitor “i. I = please 3 range, item 44 The liquid crystal display device has a third electrical extension portion whose end is connected to the end of the line == the capacitor, and the capacitance value of the scan value and the third parasitic capacitance is substantially Related to the electricity valley 47, = liquid 曰 ^ display device, which is matched with a plurality of 昼 资料 , , , The skirt includes ·, and a backlight module; and 64 200842814 - the liquid crystal display panel is disposed opposite to the back domain group, and has: a 〆, a 昼 阵列 array, which has a plurality of morphemes, any The pixel system has at least a first color sub-halogen and a second color-chromophorin The first-color sub-genogen has a first region and a second region, and the second-color sub-system has a third region and a fourth region, and a bias generating unit is aged The first region and the second region are electrically connected such that a first voltage element of the first region and a second voltage of the second region have a -first voltage difference to collectively display a first The color sub-small material data is electrically connected to the third region and the fourth region, respectively, such that a third pixel voltage of one of the third regions and a fourth pixel voltage of the fourth region are And a second color sub-dielectric data, wherein the voltage difference is different from the second voltage difference, wherein the liquid crystal display device of claim 47, wherein a first region, any second region, any third region, and any region having at least a liquid crystal capacitor and a capacitor, the liquid of the first disk or the liquid solar cell and the liquid crystal of the second region a capacitance system and the liquid crystal capacitor of the third region of f and the fourth region The liquid crystal is different, or the storage capacitor of the first region and the storage capacitor of the second region are different from the storage capacitor of the third region and the storage capacitor of the fourth region of the 2008 200842814. The liquid crystal display device of claim 47, wherein the liquid crystal display panel further comprises a driving unit, which is configured to generate a first data driving according to the color data and the second color sub-tend data respectively. And a second data driving device according to claim 49, wherein any one of the first region, any second region, any third region, and any fourth region The system has a switching element, a liquid crystal capacitor and a storage electric valley. When the switching element of the first region and the second region is = pass, the liquid crystal capacitance of the first region and the second region is based on The first data driving signal respectively generates an original first pixel voltage and an original second pixel voltage, and when the switching elements of the second region and the second region are non-conductive The bias generating unit divides the original first pixel voltage and the original first pixel voltage into the first pixel voltage and the second pixel voltage. The liquid crystal display device of claim 5, wherein the switching element of the third region and the fourth region is a turn-on day, the liquid crystal of the f-region and the fourth region The capacitor generates an original third pixel voltage and an original fourth pixel according to the second data driving signal, and when the third region 66 200842814 and the fourth region of the switching element are non-conductive, The bias generating unit adjusts the original third pixel voltage and the original fourth pixel voltage to the third pixel voltage and the fourth pixel voltage. 67