Liquid crystal display device
By interleaving pixel circuits of different colors in the liquid crystal display device and using the opposite arrangement order and additional wiring design, the problems of cloud patterns and head-shaking patterns in liquid crystal displays are solved, achieving a more uniform and stable display effect.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- AU OPTRONICS CORP
- Filing Date
- 2026-04-24
- Publication Date
- 2026-06-05
AI Technical Summary
Existing LCD monitors are prone to displaying cloud-like and swivel patterns when showing images.
The liquid crystal display device adopting the 1D1G architecture uses pixel circuits of different colors to be arranged in an alternating manner, and adopts an opposite arrangement order and additional wiring design in adjacent areas to make the polarity of the pixel circuits alternate, so as to reduce the influence of cloud patterns and head-shaking patterns.
In low frame rate display operations, it effectively reduces the occurrence of bright and dark horizontal stripes, and improves the uniformity and stability of the display.
Smart Images

Figure CN122157613A_ABST
Abstract
Description
Technical Field
[0001] This disclosure relates to a liquid crystal display device. More particularly, it relates to a liquid crystal display device employing a 1D1G architecture. Background Technology
[0002] With advancements in technology and the economy, liquid crystal displays (LCDs) have been applied to various electronic products to provide display functionality. However, current LCDs sometimes produce mura or wave-like patterns when displaying images.
[0003] Therefore, a liquid crystal display device is needed to overcome the above problems. Summary of the Invention
[0004] The purpose of this disclosure is to provide a liquid crystal display device that can mitigate the effects of the aforementioned cloud-like and wave-like patterns.
[0005] According to embodiments of this disclosure, the liquid crystal display device includes a pixel matrix. The pixel matrix includes a plurality of pixel regions. Each pixel region includes a first pixel row, a second pixel row, and a third pixel row. The first pixel row includes a plurality of first color pixel circuits and a plurality of second color pixel circuits, which are interleaved. The second pixel row is adjacent to the first pixel row and includes a plurality of first color pixel circuits and a plurality of second color pixel circuits. The first color pixel circuits and second color pixel circuits in the second pixel row are interleaved. The first color pixel circuits in the second pixel row are adjacent to the second color pixel circuits in the first pixel row. The second color pixel circuits in the second pixel row are adjacent to the first color pixel circuits in the first pixel row. The third pixel row is adjacent to the second pixel row and includes a plurality of third color pixel circuits. The second pixel row is located between the first pixel row and the third pixel row. The first pixel row and the third pixel row correspond to a first data polarity, and the second pixel row corresponds to a second data polarity, where the first data polarity is different from the second data polarity.
[0006] In some embodiments, the first color pixel circuit corresponds to red, the second color pixel circuit corresponds to green, and the third color pixel circuit corresponds to blue.
[0007] In some embodiments, the first data polarity is one of positive and negative polarity, and the second data polarity is the other of positive and negative polarity.
[0008] In some embodiments, the liquid crystal display device further includes: a plurality of data lines and a source driver. The source driver is electrically connected to the data lines to provide a plurality of pixel data to the data lines. Each of the first pixel row, the second pixel row, and the third pixel row corresponds to one of the aforementioned data lines.
[0009] According to embodiments of this disclosure, the liquid crystal display device includes a pixel matrix. The pixel matrix includes a plurality of pixel regions. Each pixel region includes a first pixel row, a second pixel row, and a third pixel row. The first pixel row includes a plurality of first color pixel circuits. Each first color pixel circuit includes a pixel circuit corresponding to a first data polarity and a pixel circuit corresponding to a second data polarity. The first data polarity is different from the second data polarity. The second pixel row includes a plurality of second color pixel circuits. Each second color pixel circuit includes a pixel circuit corresponding to both the first and second data polarities. The third pixel row includes a plurality of third color pixel circuits. Each third color pixel circuit includes a pixel circuit corresponding to either the first or second data polarity. In the first pixel row, pixel circuits corresponding to the first data polarity and pixel circuits corresponding to the second data polarity are alternately arranged. In the second pixel row, pixel circuits corresponding to the first data polarity and pixel circuits corresponding to the second data polarity are alternately arranged. Pixel circuits corresponding to the first data polarity in the first pixel row are adjacent to pixel circuits corresponding to the second data polarity in the second pixel row.
[0010] In some embodiments, the first color pixel circuit corresponds to red, the second color pixel circuit corresponds to green, and the third color pixel circuit corresponds to blue.
[0011] In some embodiments, the first data polarity is one of positive and negative polarity, and the second data polarity is the other of positive and negative polarity.
[0012] In some embodiments, the liquid crystal display device further includes: a plurality of data lines and a source driver. The source driver is electrically connected to the data lines to provide multiple pixel data to the data lines. The data lines include a first data line, a second data line, and a third data line. A first and a second portion of the first color pixel circuit are electrically connected to the first data line, and a third portion of the first color pixel circuit is electrically connected to the second data line, wherein the third portion of the first color pixel circuit is located between the first and second portions of the first color pixel circuit.
[0013] In some embodiments, a first and a second of the second color pixel circuit are electrically connected to a second data line, a third of the second color pixel circuit is electrically connected to a first data line, and the third of the second color pixel circuit is located between the first and the second of the second color pixel circuit.
[0014] In some embodiments, the third color pixel circuit described above is electrically connected to the third data line. Attached Figure Description
[0015] To make the above and other objects, features, advantages and embodiments of this disclosure more apparent and understandable, the detailed description of the accompanying drawings is as follows: Figure 1 This is a schematic diagram illustrating a liquid crystal display device using a 1D1G architecture; Figure 2 This is a schematic diagram illustrating a liquid crystal display device according to an embodiment of the present disclosure; Figure 3 This illustrates the charging state of the subtracker pattern displayed by the liquid crystal display device according to an embodiment of the present disclosure; Figure 4 This illustrates the charging state of the Hstripe pattern displayed by the liquid crystal display device according to an embodiment of the present disclosure; Figure 5 This shows the charging state of the liquid crystal display device displaying a cyan pattern according to an embodiment of the present disclosure; Figure 6 This shows the charging state of the liquid crystal display device displaying a red and green pattern according to an embodiment of the present disclosure; Figure 7 This is a schematic diagram illustrating a liquid crystal display device according to an embodiment of the present disclosure; Figure 8 This illustrates the charging state of the subtracker pattern displayed by the liquid crystal display device according to an embodiment of the present disclosure; Figure 9 This illustrates the charging state of the Hstripe pattern displayed by the liquid crystal display device according to an embodiment of the present disclosure; Figure 10 This illustrates the charging state of the liquid crystal display device displaying a cyan pattern according to an embodiment of the present disclosure; and Figure 11 This shows the charging state of the liquid crystal display device displaying a red and green pattern according to an embodiment of the present disclosure.
[0016] Explanation of reference numerals in the attached figures: 100: Liquid crystal display device 111~114: First color pixel circuit 121~124: Second color pixel circuit 131~134: Third color pixel circuit 200: Liquid crystal display device 211~214: First color pixel circuit 221~224: Second color pixel circuit 231~234: Third color pixel circuit 700: Liquid Crystal Display Device 711~714: First color pixel circuit 721~724: Second color pixel circuit 731~734: Third color pixel circuit C11~C16: Pixel row C21~C26: Pixel row C71~C76: Pixel row G11~G14: Scan lines G21~G24: Scan lines G71~G74: Scan lines PA11, PA12: Pixel areas PA21, PA22: Pixel areas PA71, P72: Pixel area R11~R14: Pixel Columns R21~R24: Pixel column R71~R74: Pixel Columns S11~S16: Data cable S21~S26: Data cable S71~S76: Data cable SD1: Source Driver SD2: Source Driver SD7: Source Driver Detailed Implementation
[0017] The following is a detailed description of the embodiments in conjunction with the accompanying drawings. However, the embodiments provided are not intended to limit the scope of this disclosure, and the description of the structural operation is not intended to limit the order of execution. Any structure resulting from the recombination of elements that produces an apparatus with equivalent technical effects is within the scope of this disclosure. Furthermore, the accompanying drawings are for illustrative purposes only and are not drawn to their original dimensions.
[0018] The terms “first,” “second,” etc., are used in this document to describe different elements. These terms are used only to distinguish elements or operations described using the same technical terms. Unless the context clearly indicates otherwise, these terms do not specifically refer to or imply any order or sequence, nor are they intended to limit this disclosure.
[0019] Please refer to Figure 1 , Figure 1This is a schematic diagram illustrating a liquid crystal display device 100 using a 1D1G architecture. The liquid crystal display device 100 includes a source driver SD1 and a pixel matrix, wherein the pixel matrix includes multiple pixel rows and multiple pixel columns, such as pixel rows C11-C16 and pixel columns R11-R14. The pixel circuits in the pixel matrix are electrically connected to multiple data lines and multiple scan lines, such as data lines S11-S16 and scan lines G11-G14, to receive pixel data transmitted by the source driver SD1 and sequentially perform on / off operations. The pixel matrix can be divided into multiple pixel regions. For example, pixel region PA11 containing pixel rows C11-C13, and pixel region PA12 containing pixel rows C14-C16. Each pixel region contains pixel circuits for three colors.
[0020] The pixel data transmitted by the source driver SD1 has polarity, such as positive and negative data polarity, to provide polarity reversal functionality for the pixel circuitry. Specifically, as... Figure 1 As shown, during a display period, the first color pixel circuits 111-114 in pixel row C11 receive positive polarity data; the second color pixel circuits 121-124 in pixel row C12 receive negative polarity data; the third color pixel circuits 131-134 in pixel row C13 receive positive polarity data; the first color pixel circuits 111-114 in pixel row C14 receive negative polarity data; the second color pixel circuits 121-124 in pixel row C15 receive positive polarity data; and the third color pixel circuits 131-134 in pixel row C16 receive negative polarity data. However, during another display period, the polarity of the pixel circuits is reversed. For example: the first color pixel circuits 111-114 in pixel row C11 receive negative polarity data; the second color pixel circuits 121-124 in pixel row C12 receive positive polarity data; the third color pixel circuits 131-134 in pixel row C13 receive negative polarity data; the first color pixel circuits 111-114 in pixel row C14 receive positive polarity data; the second color pixel circuits 121-124 in pixel row C15 receive negative polarity data; and the third color pixel circuits 131-134 in pixel row C16 receive positive polarity data. The first color pixel circuits 111-114 can be, for example, red, the second color pixel circuits 121-124 can be, for example, green, and the third color pixel circuits 131-134 can be, for example, blue.
[0021] When the liquid crystal display device 100 displays an image, the image may produce mura patterns due to insufficient charging of the pixel circuit, or the image may produce swaying patterns due to the polarity arrangement of the data.
[0022] Please refer to Figure 2 , Figure 2 This is a schematic diagram illustrating a liquid crystal display device 200 according to an embodiment of the present disclosure. The liquid crystal display device 200 includes a source driver SD2 and a pixel matrix, wherein the pixel matrix includes multiple pixel rows and multiple pixel columns, such as pixel rows C21-C26 and pixel columns R21-R24. Pixel circuits in the pixel matrix are electrically connected to multiple data lines and multiple scan lines, such as data lines S21-S26 and scan lines G21-G24, to receive pixel data transmitted by the source driver SD2 and sequentially perform on / off operations. The pixel matrix can be divided into multiple pixel regions. For example, pixel region PA21 containing pixel rows C21-C23, and pixel region PA22 containing pixel rows C24-C26. Each pixel region includes pixel circuits for three colors.
[0023] Pixel row C21 includes multiple first-color pixel circuits 211 and 213 and multiple second-color pixel circuits 222 and 224. Pixel row C22 includes multiple first-color pixel circuits 212 and 214 and multiple second-color pixel circuits 221 and 223. Pixel row C23 includes multiple third-color pixel circuits 231-234. Pixel row C24 includes multiple first-color pixel circuits 211 and 213 and multiple second-color pixel circuits 222 and 224. Pixel row C25 includes multiple first-color pixel circuits 212 and 214 and multiple second-color pixel circuits 221 and 223. Pixel row C26 includes multiple third-color pixel circuits 231-234.
[0024] Considering pixel region PA21, in pixel rows C21 and C22, the first color pixel circuits 211 and 213 are alternately arranged with the second color pixel circuits 222 and 224, and the first color pixel circuits 212 and 214 are alternately arranged with the second color pixel circuits 221 and 223. Similarly, considering pixel region PA22, in pixel rows C22 and C25, the first color pixel circuits 211 and 213 are alternately arranged with the second color pixel circuits 222 and 224, and the first color pixel circuits 212 and 214 are alternately arranged with the second color pixel circuits 221 and 223. In some embodiments of this disclosure, each of pixel rows C21-C22 and C24-C25 contains only the first color pixel circuit and the second color pixel circuit, while pixel rows C23 and C26 contain only the third color pixel circuit. However, the embodiments of this disclosure are not limited thereto.
[0025] Considering pixel region PA21, in two adjacent pixel rows, for example, in pixel rows C21 and C22, the first color pixel circuits 211 and 213 in pixel row C21 are adjacent to the second color pixel circuits 221 and 223 in pixel row C22, and the second color pixel circuits 222 and 224 in pixel row C21 are adjacent to the first color pixel circuits 212 and 214 in pixel row C22. Similarly, considering pixel region PA22, in two adjacent pixel rows C24 and C25, the first color pixel circuits 211 and 213 in pixel row C24 are adjacent to the second color pixel circuits 221 and 223 in pixel row C25, and the second color pixel circuits 222 and 224 in pixel row C24 are adjacent to the first color pixel circuits 212 and 214 in pixel row C25.
[0026] Consider pixel region PA21. In three adjacent pixel rows, such as rows C21-C23, rows C21 and C23 correspond to a first data polarity (e.g., positive polarity), while row C22 corresponds to a second data polarity (e.g., negative polarity). The second data polarity of row C22 differs from the first data polarity of rows C21 and C23, and row C22 is located between rows C21 and C23. Similarly, considering pixel region PA22, in three adjacent pixel rows C24-C26, rows C24 and C26 correspond to a first data polarity, while row C25 corresponds to a second data polarity. The second data polarity of row C25 differs from the first data polarity of rows C24 and C26, and row C22 is located between rows C24 and C26.
[0027] In embodiments of this disclosure, the first color pixel circuits 211-214 may be, for example, red, the second color pixel circuits 221-224 may be, for example, green, and the third color pixel circuits 231-234 may be, for example, blue. However, embodiments of this disclosure are not limited thereto. In some embodiments, the first color pixel circuits 211-214 may be, for example, green, and the second color pixel circuits 221-224 may be, for example, red.
[0028] In the liquid crystal display device 200, to make the bright and dark areas appear mixed and less prone to being observed as horizontal lines, the pixel circuits in adjacent areas are arranged in opposite orders (a star-shaped distribution). Furthermore, to eliminate head-shaking patterns in low frame rate display operations, the first color pixel circuit and the second color pixel circuit are interleaved, so that the first color pixel circuit and the second color pixel circuit in each of the pixel columns R21 to R24 have interleaved positive and negative polarities.
[0029] Please refer to Figure 3 , Figure 3This illustrates the charging state of the liquid crystal display device 200 displaying a subtracker pattern according to an embodiment of the present disclosure. When the liquid crystal display device 200 displays the subtracker pattern, both the red and green pixel circuits are fully charged, while the blue pixel circuits do not exhibit color difference due to their inherent characteristics. Therefore, the liquid crystal display device 200 presents a uniform overall appearance.
[0030] Please refer to Figure 4 , Figure 4 This illustrates the charging state of the liquid crystal display device 200 displaying an Hstripe pattern according to an embodiment of the present disclosure. When the liquid crystal display device 200 displays the Hstripe pattern, insufficient charging occurs because the pixel circuits are not fully open. However, since all pixel circuits are undercharged, the liquid crystal display device 200 displays a uniform overall charging state.
[0031] Please refer to Figure 5 , Figure 5 This illustrates the charging state of the liquid crystal display device 200 displaying a cyan pattern according to an embodiment of the present disclosure. When the liquid crystal display device 200 displays a cyan pattern, insufficient charging occurs because the pixel circuits are not fully open. However, all green pixel circuits are undercharged, resulting in a uniform overall appearance of the liquid crystal display device 200.
[0032] Please refer to Figure 6 , Figure 6 This illustrates the charging state of the liquid crystal display device 200 displaying a red-green pattern according to an embodiment of the present disclosure. When the liquid crystal display device 200 displays a red-green pattern, since all pixel circuits are fully charged, the liquid crystal display device 200 exhibits uniformity overall.
[0033] Please refer to Figure 7 , Figure 7This is a schematic diagram illustrating a liquid crystal display device 700 according to an embodiment of the present disclosure. The liquid crystal display device 700 includes a source driver SD7 and a pixel matrix, wherein the pixel matrix includes multiple pixel rows and multiple pixel columns, such as pixel rows C71-C76 and pixel columns R71-R74. Pixel circuits in the pixel matrix are electrically connected to multiple data lines and multiple scan lines, such as data lines S71-S76 and scan lines G71-G74, to receive pixel data transmitted by the source driver SD7 and sequentially perform on / off operations. The pixel matrix can be divided into multiple pixel regions. For example, pixel region PA71 containing pixel rows C71-C73, and pixel region PA72 containing pixel rows C74-C76. Each pixel region includes pixel circuits for three colors. Considering pixel region PA71, pixel row C71 includes multiple first-color pixel circuits 711-714, pixel row C72 includes multiple second-color pixel circuits 721-724, and pixel row C73 includes multiple third-color pixel circuits 731-734. Considering pixel region PA72, pixel row C74 includes multiple first-color pixel circuits 711-714, pixel row C75 includes multiple second-color pixel circuits 721-724, and pixel row C76 includes multiple third-color pixel circuits 731-734. In some embodiments of this disclosure, each of pixel rows C71 and C74 includes only first-color pixel circuits; each of pixel rows C72 and C75 includes only second-color pixel circuits; and pixel rows C73 and C76 include only third-color pixel circuits. However, the embodiments of this disclosure are not limited thereto.
[0034] In pixel rows C72 and C75, the second color pixel circuits 721-724 also correspond to the first data polarity and the second data polarity, and are interleaved. For example, the second color pixel circuits 721 and 723 correspond to the second data polarity, and the second color pixel circuits 722 and 724 correspond to the first data polarity, and the second color pixel circuits 721-724 are interleaved.
[0035] In each of pixel rows C73 and C76, the third color pixel circuits 731-734 all have the same data polarity. For example, in pixel row C73, the third color pixel circuits 731-734 all have a first data polarity. And, for example, in pixel row C76, the third color pixel circuits 731-734 all have a second data polarity.
[0036] Considering pixel region PA71, in two adjacent pixel rows, for example, in pixel rows C71 and C72, the first color pixel circuits 711 and 713 with a first data polarity in pixel row C71 are adjacent to the second color pixel circuits 721 and 723 with a second data polarity in pixel row C72; the first color pixel circuits 712 and 714 with a second data polarity in pixel row C71 are adjacent to the second color pixel circuits 722 and 724 with a first data polarity in pixel row C72. As another example, considering pixel region PA72, in pixel rows C74 and C75, the first color pixel circuits 711 and 713 with a second data polarity in pixel row C74 are adjacent to the second color pixel circuits 721 and 723 with a first data polarity in pixel row C75; the first color pixel circuits 712 and 714 with a first data polarity in pixel row C74 are adjacent to the second color pixel circuits 722 and 724 with a second data polarity in pixel row C75.
[0037] To achieve the above design, the liquid crystal display device 700 provides a specific wiring design to adjust the connection relationship of the pixel circuits in pixel rows C71, C72, C74, and C75.
[0038] For example, consider pixel rows C71 to C73. Pixel row C71 is adjacent to data line S71, pixel row C72 is adjacent to data line S72, and pixel row C73 is adjacent to data line S73. The first color pixel circuits 711 and 713 of pixel row C71 are electrically connected to data line S71 to receive pixel data with a first data polarity, and the first color pixel circuits 712 and 714 of pixel row C71 are electrically connected to data line S72 through additional wiring to receive pixel data with a second data polarity. The first color pixel circuits 712 and 714 are interleaved with the first color pixel circuits 711 and 713. The second color pixel circuits 721 and 723 of pixel row C72 are electrically connected to data line S72 to receive pixel data with a second data polarity, and the second color pixel circuits 722 and 724 of pixel row C72 are electrically connected to data line S71 through additional wiring to receive pixel data with a first data polarity. The second color pixel circuits 722 and 724 are interleaved with the second color pixel circuits 721 and 723. The third color pixel circuits 731 to 734 of pixel row C73 are all electrically connected to data line S73 to receive pixel data with a first data polarity.
[0039] For example, consider pixel rows C74 to C76. Pixel row C74 is adjacent to data line S74, pixel row C75 is adjacent to data line S75, and pixel row C76 is adjacent to data line S76. The first color pixel circuits 711 and 713 of pixel row C74 are electrically connected to data line S74 to receive pixel data with a second data polarity, and the first color pixel circuits 712 and 714 of pixel row C74 are electrically connected to data line S75 through additional wiring to receive pixel data with a first data polarity. The first color pixel circuits 712 and 714 are interleaved with the first color pixel circuits 711 and 713. The second color pixel circuits 721 and 723 of pixel row C75 are electrically connected to data line S75 to receive pixel data with a first data polarity, and the second color pixel circuits 722 and 724 of pixel row C75 are electrically connected to data line S74 through additional wiring to receive pixel data with a second data polarity. The second color pixel circuits 722 and 724 are interleaved with the second color pixel circuits 721 and 723. The third color pixel circuits 731 to 734 of pixel row C76 are all electrically connected to data line S76 to receive pixel data with a second data polarity.
[0040] In embodiments of this disclosure, the first color pixel circuits 711-714 may be, for example, red, the second color pixel circuits 721-724 may be, for example, green, and the third color pixel circuits 731-734 may be, for example, blue. However, embodiments of this disclosure are not limited thereto. In some embodiments, the first color pixel circuits 711-714 may be, for example, green, and the second color pixel circuits 721-724 may be, for example, red.
[0041] In the liquid crystal display device 700, to make the bright and dark areas appear mixed and less prone to being observed as horizontal stripes, the pixel data in adjacent areas are arranged in opposite orders (cloverleaf distribution). Furthermore, to eliminate head-shaking patterns in low frame rate display operations, additional wiring is used to interleave the polarities of the data received by the first color pixel circuit and the second color pixel, so that the first color pixel circuit and the second color pixel circuit in each of the pixel columns R71 to R74 have interleaved positive and negative polarities.
[0042] Please refer to Figure 8 , Figure 8 This illustrates the charging state of the liquid crystal display device 700 displaying a subtracker pattern according to an embodiment of the present disclosure. When the liquid crystal display device 700 displays the subtracker pattern, both the red and green pixel circuits are fully charged, while the blue pixel circuit does not exhibit color difference due to its inherent characteristics. Therefore, the liquid crystal display device 700 presents a uniform overall appearance.
[0043] Please refer to Figure 9 , Figure 9 This illustrates the charging state of the liquid crystal display device 700 displaying an Hstripe pattern according to an embodiment of the present disclosure. When the liquid crystal display device 700 displays the Hstripe pattern, insufficient charging occurs because the pixel circuits are not fully open. However, since all pixel circuits are undercharged, the liquid crystal display device 700 displays a uniform overall charging state.
[0044] Please refer to Figure 10 , Figure 10 This illustrates the charging state of the liquid crystal display device 700 displaying a cyan pattern according to an embodiment of the present disclosure. When the liquid crystal display device 700 displays a cyan pattern, insufficient charging occurs because the pixel circuits are not fully open. However, all green pixel circuits are undercharged, resulting in a uniform overall appearance of the liquid crystal display device 700.
[0045] Please refer to Figure 11 , Figure 11 This illustrates the charging state of the liquid crystal display device 700 displaying a red-green pattern according to an embodiment of the present disclosure. When the liquid crystal display device 700 displays a red-green pattern, since all pixel circuits are fully charged, the liquid crystal display device 700 exhibits uniformity overall.
[0046] Although this disclosure has been described above with reference to several embodiments, it is not intended to limit this disclosure. Any person skilled in the art to which this disclosure pertains may make various changes and modifications without departing from the concept and scope of this disclosure. Therefore, the scope of protection of this disclosure shall be determined by the claims.
Claims
1. A liquid crystal display device, comprising: A pixel matrix, containing multiple pixel regions, where Each of these pixel regions includes a first pixel row, a second pixel row, and a third pixel row; The first pixel row includes a plurality of first color pixel circuits and a plurality of second color pixel circuits, and the first color pixel circuits and the second color pixel circuits in the first pixel row are arranged alternately; The second pixel row is adjacent to the first pixel row and includes a plurality of first color pixel circuits and a plurality of second color pixel circuits. The first color pixel circuits and second color pixel circuits in the second pixel row are staggered. The first color pixel circuits in the second pixel row are adjacent to the second color pixel circuits in the first pixel row, and the second color pixel circuits in the second pixel row are adjacent to the first color pixel circuits in the first pixel row. The third pixel row is adjacent to the second pixel row and contains multiple third color pixel circuits; The second pixel row is located between the first pixel row and the third pixel row; and The first pixel row and the third pixel row correspond to a first data polarity, and the second pixel row corresponds to a second data polarity, wherein the first data polarity is different from the second data polarity.
2. The liquid crystal display device as claimed in claim 1, wherein the first color pixel circuit corresponds to red, the second color pixel circuit corresponds to green, and the third color pixel circuit corresponds to blue.
3. The liquid crystal display device as claimed in claim 1, wherein the first data polarity is one of positive and negative polarity, and the second data polarity is the other of positive and negative polarity.
4. The liquid crystal display device as claimed in claim 1, further comprising: Multiple data cables; and A source driver is electrically connected to the data lines to provide multiple pixel data to the data lines; Each of the first pixel row, the second pixel row, and the third pixel row corresponds to one of the data lines.
5. A liquid crystal display device, comprising: A pixel matrix, containing multiple pixel regions, where Each of these pixel regions includes a first pixel row, a second pixel row, and a third pixel row; The first pixel row includes a plurality of first color pixel circuits, each first color pixel circuit including a pixel circuit corresponding to a first data polarity and a pixel circuit corresponding to a second data polarity, wherein the first data polarity is different from the second data polarity; The second pixel row includes a plurality of second color pixel circuits, the second color pixel circuits including pixel circuits corresponding to the first data polarity and pixel circuits corresponding to the second data polarity; The third pixel row includes a plurality of third color pixel circuits, the third color pixel circuits including pixel circuits corresponding to one of the first data polarity and the second data polarity; In the first pixel row, pixel circuits corresponding to the first data polarity and pixel circuits corresponding to the second data polarity are alternately arranged; In the second pixel row, the pixel circuits corresponding to the first data polarity and the pixel circuits corresponding to the second data polarity are alternately arranged; The pixel circuit in the first pixel row corresponding to the first data polarity is adjacent to the pixel circuit in the second pixel row corresponding to the second data polarity.
6. The liquid crystal display device as claimed in claim 5, wherein the first color pixel circuit corresponds to red, the second color pixel circuit corresponds to green, and the third color pixel circuit corresponds to blue.
7. The liquid crystal display device as claimed in claim 5, wherein the first data polarity is one of positive and negative polarity, and the second data polarity is the other of positive and negative polarity.
8. The liquid crystal display device as claimed in claim 5, further comprising: Multiple data cables; and A source driver is electrically connected to the data lines to provide multiple pixel data to the data lines; in The data lines include a first data line, a second data line, and a third data line. A first and a second of the first color pixel circuits are electrically connected to the first data line, and a third of the first color pixel circuits is electrically connected to the second data line. The third of the first color pixel circuits is located between the first and the second of the first color pixel circuits.
9. The liquid crystal display device of claim 8, wherein a first and a second of the second color pixel circuits are electrically connected to the second data line, a third of the second color pixel circuits is electrically connected to the first data line, and the third of the second color pixel circuits is located between the first and the second of the second color pixel circuits.
10. The liquid crystal display device of claim 9, wherein the third color pixel circuits are electrically connected to the third data line.