1. Field of the Invention
The present invention relates to a Liquid Crystal Display (LCD), and more particularly, to an LCD with two-dot inversion capable of saving power consumption.
2. Description of the Prior Art
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The gate driving circuit 110 comprises a plurality of gate lines G1˜GN for generating gate driving signals SG1˜SGN in order. The data driving circuit 120 comprises a plurality of data lines D1˜DM for generating data driving signals SD1˜SDM. Each of the gate lines G1˜GN is a straight line parallel with each other and each of the data line D1˜DM is a straight line parallel with each other. The pixel area 130 comprises a pixel array with M columns and N rows. The pixel array comprises (M×N) pixels P11˜PMN. The pixels of the pixel array are interwoven by the gate lines G1˜GN across the data lines D1˜DM and are driven by the gate driving signals generated by the corresponding gate lines for receiving the data driving signals generated by the corresponding data lines. For example, when the pixel P11 receives the gate driving signal SG1, the pixel P11 receives the data signal SD1 so as to display the image. When the pixel P12 receives the gate driving signal SG2, the pixel P12 receives the data signal SD1 so as to display the image. When the pixel P21 receives the gate driving signal SG1, the pixel P21 receives the data signal SD2 so as to display the image. When the pixel P22 receives the gate driving signal SG2, the pixel P22 receives the data signal SD2 so as to display the image, and so on.
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However, in the conventional LCD 100, since the gate lines are parallel with each other and the data lines are parallel with each other, and the gate lines are perpendicular across the data lines, for the purpose of displaying frame by dot inversion, the polarities of the data driving signals carried by the data lines have to be inverted every time a gate driving signal passes by, which causes too much power consumption and is quite inconvenient for the user.
The present invention provides an LCD with two-dot inversion. The LCD comprises a plurality of gate lines, a plurality of data lines and a pixel array. The plurality of gate lines are utilized for transmitting gate driving signals. The plurality of data lines are utilized for transmitting data driving signals. The pixel array comprises a plurality of columns of pixels. Each row of the plurality of the columns of the pixels comprises a pixel so as to form the pixel array and the pixel array displays images according to the received gate driving signals and the received data driving signals. One of the plurality of the columns of the pixels is disposed between two adjacent gate lines and between two adjacent data lines. A first data line of the plurality of the data lines is coupled to pixels of a first column of a first pair of the plurality of the columns of the pixels and to pixels of a second column of a second pair of the plurality of the columns of the pixels, wherein the first column is separated from the second column by at least two columns.
The present invention further provides an LCD with two-dot inversion capable of saving power consumption. The LCD comprises a first, a second, a third and a fourth gate lines, a first and a second data lines, and a pixel array. The first, the second, the third and the fourth gate lines are utilized for transmitting gate driving signals. The first and the second data lines are utilized for transmitting data driving signals. The pixel array comprises a first, a second, a third, a fourth, a fifth and a sixth pixels. The first pixel is disposed at a first row and a first column of the pixel array. The first pixel is coupled to the first gate line and the first data line for displaying images according to the received gate driving signals and the received data driving signals. The second pixel is disposed at the first row and a second column of the pixel array. The second pixel is coupled to the second gate line and the first data line for displaying the images according to the received gate driving signals and the received data driving signals. The third pixel is disposed at the first row and a third column of the pixel array. The third pixel is coupled to the first gate line and the second data line for displaying the images according to the received gate driving signals and the received data driving signals. The fourth pixel is disposed at the first row and a fourth column of the pixel array. The fourth pixel is coupled to the second gate line and the second data line for displaying the images according to the received gate driving signals and the received data driving signals. The fifth pixel is disposed at a second row and the third column of the pixel array. The fifth pixel is coupled to the third gate line and the first data line for displaying the images according to the received gate driving signals and the received data driving signals. The sixth pixel is disposed at the second row and the fourth column of the pixel array. The sixth pixel is coupled to the fourth gate line and the first data line for displaying the images according to the received gate driving signals and the received data driving signals.
These and other objectives of the present invention will no doubt become obvious to those of ordinary skill in the art after reading the following detailed description of the preferred embodiment that is illustrated in the various figures and drawings.
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A gate driving circuit 410 comprises a plurality of gate lines G1˜GN. The gate driving circuit 410 is utilized for sequentially generating the gate driving signals SG1˜SGN and transmitting the gate driving signals SG1˜SGN respectively through the gate lines G1˜GN. The data driving circuit 420 comprises a plurality of data lines D1˜DM. The data driving circuit 420 is utilized for generating the data driving signal SD1˜SDM and transmitting the data driving signals SD1˜SDM respectively through the data lines D1˜DM. Each of the gate lines G1˜GN is a straight line parallel with each other. Each of the data line D1˜DM is designed as a curved line with a shape like the letter “S”. More particularly, the data lines designed by the present invention, in the pixel area 430, are curved with several bends between the two corresponding pair of columns of pixels. For example, the data lines D2 is disposed between the first column of pixels and the second column of pixels (the first pair of columns of pixels), and the third column of pixels and the fourth column of pixels (the second pair of columns of pixels). More particularly, in the first row of the pixel area 430, the data line D2 is disposed between the pixel P11 and the pixel P21 (the first pair of columns of pixels). In the second row of the pixel area 430, the data line D2 is curved between the pixel P32 and the pixel P42 (the second pair of columns of pixels). In the third row of pixel area 430, the data line D2 is curved back between the pixel P13 and the pixel P23 (the first pair of columns of pixels). In the fourth row of the pixel area 430, the data line D2 is curved again between the pixel P34 and the pixel P44 (the second pair of columns of pixels) (not shown), and so on. The data line D3 is disposed in the pixel area 430 between the third and fourth columns of pixels (the first pair of columns of pixels) and the fifth and sixth columns of pixels (the second pair of columns of pixels). More precisely, in the first row of the pixel area 430, the data line D3 is disposed between the pixel P31 and the pixel P41 (the first pair of columns of pixels). In the second row of the pixel area 430, the data line D3 is curved between the pixel P52 and the pixel P62 (the second pair of columns of pixels). In the third row of pixel area 430, the data line D3 is curved back between the pixel P33 and the pixel P43 (the first pair of columns of pixels). In the fourth row of the pixel area 430, the data line D3 is curved again between the pixel P54 and the pixel P64 (the second pair of columns of pixels) (not shown), and so on. The rest data lines are disposed in the similar way and hereinafter will not be repeated again.
The pixel area 430 comprises a pixel array with M columns and N rows. The pixel array comprises (M×N) pixels P11˜PMN. The pixels of the pixel array are interwoven by the gate lines G1˜GN across the data lines D1˜DM and are driven by the gate driving signals generated by the corresponding gate lines for receiving the data driving signals generated by the corresponding data lines. For instance, the pixel P11 is coupled to the gate line G1 and the data line D2. When the pixel P11 receives the gate driving signal SG1, the pixel P11 receives the data signal SD2 so as to display the image. The pixel P21 is coupled to the gate line G2 and the data line D2. When the pixel P21 receives the gate driving signal SG2, the pixel P21 receives the data signal SD2 so as to display the image. The pixel P12 is coupled to the gate line G3 and the data line D1. When the pixel P12 receives the gate driving signal SG3, the pixel P12 receives the data signal SD1 so as to display the image. The pixel P22 is coupled to the gate line G4 and the data line D1. When the pixel P22 receives the gate driving signal SG4, the pixel P22 receives the data signal SD1 so as to display the image. The pixel P31 is coupled to the gate line G1 and the data line D3. When the pixel P31 receives the gate driving signal SG1, the pixel P31 receives the data signal SD3 so as to display the image. The pixel P41 is coupled to the gate line G2 and the data line D3. When the pixel P41 receives the gate driving signal SG2, the pixel P41 receives the data signal SD3 so as to display the image, and so on. The pixel P32 is coupled to the gate line G3 and the data line D2. When the pixel P32 receives the gate driving signal SG3, the pixel P32 receives the data signal SD2 so as to display the image, and so on. In addition, each pixel (for example, the pixel P32 and the Pixel P42 of the
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In conclusion, in the LCD provided by the present invention, since the data lines in the pixel area have the shape like the letter “S”, the data driving signals on the data lines does not have to be inverted within one frame. In this way, the power consumption of the LCD is saved, causing a great convenience.
Those skilled in the art will readily observe that numerous modifications and alterations of the device and method may be made while retaining the teachings of the invention.
Number | Date | Country | Kind |
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097138668 | Oct 2008 | TW | national |