Provided is an array substrate pixel connection structure, including data lines, being aligned side by side along a first direction; gate lines being aligned side by side along a second direction; the data lines and the gate lines crisscrossing to define sub pixels, and the sub pixels including a first row to a fourth row of sub pixels which are aligned in order along the second direction, the sub pixels in the first, the second row of sub pixels being coupled to the data line which is adjacent, and the sub pixels in the third, the fourth row of sub pixels being coupled to the data line which is adjacent, and the data line which the third, the fourth rows of sub pixels are coupled and the data line which the first, the second rows of sub pixels are coupled have two alignment directions which are opposite.

A flat panel display includes: a substrate that includes a display region and a non-display region at a periphery of the display region; a pixel array disposed on the substrate of the display region; an input pad part disposed on the substrate of the non-display region; a bonding pad part disposed on the substrate of the non-display region, the bonding pad part including a plurality of output pads connected to the pixel array and a plurality of input pads connected to the input pad part; and a protective layer disposed on the substrate of the non-display region, the protective layer having openings formed therein that expose portions of the bonding pad part and the input pad part, wherein the opening of the protective layer is smaller than the bonding pad part, wherein the protective layer is thinner at a portion that overlaps the bonding pad part than at other portions.

A method of manufacturing a display device is provided. The display device includes a display region divided into a first display region and a second display region by a border region extending in the second direction, a plurality of data lines including a plurality of first data lines arranged in the first display region, and a plurality of second data lines arranged in the second display region. Each of the plurality of first data lines and each of the plurality of second data lines are electrically isolated from each other. The method includes steps of forming a plurality of conductive lines on a substrate extending from a top side to a bottom side of the display region in the first direction, and separating the plurality of conductive lines into the plurality of first data lines and the plurality of second data lines.

According to one embodiment, a liquid crystal display device includes a first substrate, a second substrate, a liquid crystal layer, and a first drive module. A first source line is located between a first divisional electrode and a second divisional electrode. One frame period includes a first display period, a second display period, a sense period, and a first pre-charge period. The first drive module supplies a first image signal having a first polarity to the first source line in the first display period, supplies a first pre-charge signal having a second polarity to the first source line in the first pre-charge period, and supplies the first image signal having the first polarity to the first source line in the second display period.

The invention discloses a GOA circuit, a display device and a drive method of a GOA circuit, the GOA circuit is set to be GOA units including a plurality of levels, a N leveled GOA unit is applied to charge a N leveled scanning line of a display region of the display device, the N leveled scanning line is connected to a first gate all on signal and a second gate all on signal, which can guarantee scanning lines corresponding to all the GOA units are being charged under control of the first gate all on signal and the second gate all on signal. The invention can carry out an all gate on function according to the method above.

A method of manufacturing a display device is provided. The display device includes a display region divided into a first display region and a second display region by a border region extending in the second direction, a plurality of data lines including a plurality of first data lines arranged in the first display region, and a plurality of second data lines arranged in the second display region. Each of the plurality of first data lines and each of the plurality of second data lines are electrically isolated from each other. The method includes steps of forming a plurality of conductive lines on a substrate extending from a top side to a bottom side of the display region in the first direction, and separating the plurality of conductive lines into the plurality of first data lines and the plurality of second data lines.

A system and device for driving high resolution monitors while reducing artifacts thereon. Utilization of Z-inversion polarity driving techniques to drive pixels in a display reduces power consumption of the display but tends to generate visible horizontal line artifacts caused by capacitances present between the pixels and data lines of the display. By introducing a physical shield between the pixel and data line elements, capacitance therebetween can be reduced, thus eliminating the cause of the horizontal line artifacts. The shield may be a common voltage line (Vcom) of the display.

The invention provides a liquid crystal display device capable of preventing a reduction in display quality by suppressing the occurrence of flicker during alternating-voltage drive, as well as a method for driving the same. Overshoot drive is performed during a first frame period, which is shortened to such an extent that a positive effective area and a negative effective area are approximately equal in size. The duration of the first frame period is set to be greater than or equal to a quarter of one frame period at a refresh rate of 60 Hz but less than one frame period. This renders it possible to make adjustments such that luminance is inhibited from abruptly dropping immediately after a polarity change, and also luminance is prevented from becoming excessively high due to overshoot drive, and therefore, the occurrence of flicker due to flexoelectric polarization during alternating-voltage drive can be suppressed.

An active matrix substrate (12A) of a liquid crystal display device (10) includes: drive electrodes (32A, 32B) a pair of which are arranged in each pixel; pixel electrodes (36) each of which is provided in each pixel; first switching elements (34A) each of which is connected to one of the pair of drive electrode (32A); second switching elements (34B) each of which is connected to the other drive electrode (32B); third switching elements (34C) connected to the pixel electrodes (36); first source lines (30A) connected to the group of the first switching elements (34); second source lines (30B) connected to the group of the second switching elements (34B); third source lines (30C) connected to the group of the third switching elements (30C); and a plurality of gate lines (28).

A liquid crystal display device wherein a first substrate and a second substrate are bonded together by a sealing material, a pixel electrode, a common electrode, a shift register, a clock line, and a power supply line are formed on the first substrate, a plurality of conductive particles are mixed into the sealing material, the plurality of conductive particles are maintained at a same potential as the common electrode, and the plurality of conductive particles are disposed at a position overlapping at least a part of the power supply line, when viewed from a normal direction of the first substrate.