Disclosed is a touch sensitive display apparatus which decreases a load of each of a plurality of touch electrodes and reduces a load deviation between the plurality of touch electrodes, thereby enhancing image quality. The touch sensitive display apparatus comprises a touch sensitive panel. The touch panel comprises a plurality of touch electrodes comprising at least a first touch electrode. The first touch electrode comprises a plurality of first touch electrode lines that are parallel to each other. A first touch signal line is connected to the plurality of first touch electrode lines of the first touch electrode, and the first touch electrode is driven for image display and touch sensing via the first touch signal line. A first connecting line is in a different layer than the first touch electrode lines, and the first connecting line is connected to the plurality of first touch electrode lines.

A liquid crystal device includes a liquid crystal panel and a liquid crystal driver. The liquid crystal panel includes a segment electrode, a segment signal line connected to the segment electrode, and a segment signal line connected to the segment electrode. The liquid crystal driver includes a segment terminal to be connected to the segment signal line, a segment driving circuit that outputs a segment driving signal to the segment terminal, a segment terminal to be connected to the segment signal line, and an anomalous segment detection circuit that detects anomalous driving of the segment electrode based on a segment monitoring signal that is input to the segment terminal from the segment electrode via the segment signal line.

According to one embodiment, a liquid crystal device includes a first liquid crystal cell and a second liquid crystal cell bonded to the first liquid crystal cell. Each of the first liquid crystal cell and the second liquid crystal cell includes a first substrate, a second substrate, a liquid crystal layer, a sealant bonding the first substrate and the second substrate together, one or more first spacers disposed inside the sealant and holding the gap, and a plurality of second spacers disposed in an effective area surrounded by the sealant and holding the gap.

Described herein is a polymorphic display, which is a unitary apparatus constructed such that a wide variety of electro-optic functions are enabled. The polymorphic display is used in an intelligent container system for monitoring and evaluating actions taken at the container system. In this way, relationships between displayed information and actions may be determined. The polymorphic display, even when having multiple pixels, enables sharing of selected structures among the pixels. In a multi-pixel construction, there is a set of pixels in the display that exhibit one set of operable properties, such as particular stability, sequencing, and switching properties, and another set of pixels that are different from the first set. That is, they have different stability, sequencing, or switching properties. In such a way, a highly flexible polymorphic display may be construed to satisfy a wide range of display needs, including novel applications on intelligent container systems.

A pixel arrangement structure, a display substrate, a display device, and a mask plate group. The pixel arrangement structure includes multiple minimum repeat units arranged in an array; each minimum repeat unit includes a first color sub-pixel, a second color sub-pixel, and a third color sub-pixel; a first connecting line between the centers of the first color sub-pixel and the second color sub-pixel extends along a first direction, and a second connecting line between the centers of the first color sub-pixel and the third color sub-pixel extends along a second direction; the orthographic projection of the first color sub-pixel on a first straight line falls into the orthographic projection of the third color sub-pixel on the first straight line, and the orthographic projection of the first color sub-pixel on a second straight line falls into the orthographic projection of the second color sub-pixel on the second straight line.

A display device includes a substrate, a transistor, a pixel electrode, a first conductive layer and a second conductive layer. The transistor is disposed on the substrate. The pixel electrode is disposed on the substrate. The pixel electrode is electrically connected to the transistor. The first conductive layer is disposed on the pixel electrode. The first conductive layer has a first slit. The second conductive layer is disposed on the pixel electrode. The second conductive layer has a second slit. The first slit and the second slit are overlapped with the pixel electrode.

The display device includes a display panel and a front surface panel that is superimposed with the display panel, and that is switched between a reflective state in which incident light is reflected and a transmissive state in which incident light is transmitted. The front surface panel can detect presence of an object to be detected.

A display panel and a fabrication method thereof are provided. The display panel includes pixels, data lines and scan lines. The pixels are arranged in pixel rows and pixel columns, and each pixel has subpixels. The data lines are configured to transmit data signals to the pixels, and each data line has a non-straight and continuously curved shape or a non-straight and continuously bent shape. The scan lines are configured to sequentially transmit scan signals to the pixels. The subpixels of each pixel are coupled to different scan lines, and each data line is curved or bent with respect to a unit of one pixel. Accordingly, the display panel of the invention can avoid the problems of poor image display and vertical line (V-line) defects as well as reducing power consumption.

A liquid crystal device (300) includes a liquid crystal panel (200) and a liquid crystal driver (100) that drives the liquid crystal panel (200). The liquid crystal panel (200) includes a segment electrode (ESD1) and segment signal lines (LSD1, LSD2) that are connected to the segment electrode (ESD1). The liquid crystal driver (100) includes segment terminals (TSD1, TSD2) to be connected to the segment signal lines (LSD1, LSD2), and a segment driving circuit. The segment driving circuit outputs a first segment driving signal to the segment signal line (LSD1) through the segment terminal (TSD1), and outputs a second segment driving signal to the segment signal line (LSD2) through the segment terminal (TSD2).

The disclosure provides a pixel electrode structure and a liquid crystal display (LCD) panel. The pixel electrode structure includes a main electrode, a plurality of branch electrodes, and a plurality of gaps. The main electrode is a strip electrode with a zigzag shape. A junction electric field is formed in a liquid crystal cell to which the main electrode corresponds, which may improve convergence and collimation of light and increase light transmittance through a display panel. Furthermore, a width of the main electrode is reduced, which further reduces widths of black lines appearing on a location corresponding to the main electrode and further increases light transmittance of the display panel.