According to an aspect, there is provided a display unit for generating a display output, comprising a first light source; a first back polarizer arranged to polarize light from the first light source in a first polarization direction; a second light source; a second back polarizer arranged to polarize light from the second light source in a second polarization direction that is orthogonal to the first polarization direction; a first substrate; a second substrate; a liquid crystal layer positioned between the first substrate and the second substrate, wherein the first substrate, second substrate and liquid crystal layer are arranged to receive light from the first light source that has been polarized by the first back polarizer and receive light from the second light source that has been polarized by the second back polarizer; and a front polarizer arranged to polarize light, the front polarizer being for polarizing light that has passed through the liquid crystal layer; wherein operating the first light source to generate light generates a positive display output, and operating the second light source to generate light generates a negative display output.

A display device includes two adjacent pixel electrodes spaced apart from each other by a gap extending in a first direction, at least one signal line extending in the first direction and having at least one protrusion at at least one side thereof, and two adjacent common electrode lines spaced apart from each other. The orthogonal projection of one/the other common electrode line on the substrate is located between the orthogonal projection of the signal line on the substrate and the orthogonal projection of one/the other pixel electrode on the substrate. Each common electrode line has a bend segment bending away from the signal line, wherein the protrusion of the at least one signal line positionally corresponds to the bend segment of each common electrode line, and the length of the protrusion is not larger than the length of the bend segment.

A display device includes two adjacent pixel electrodes spaced apart from each other by a gap extending in a first direction, at least one signal line extending in the first direction and having at least one protrusion at at least one side thereof, and two adjacent common electrode lines spaced apart from each other. The orthogonal projection of one/the other common electrode line on the substrate is located between the orthogonal projection of the signal line on the substrate and the orthogonal projection of one/the other pixel electrode on the substrate. Each common electrode line has a bend segment bending away from the signal line, wherein the protrusion of the at least one signal line positionally corresponds to the bend segment of each common electrode line, and the length of the protrusion is not larger than the length of the bend segment.

An active matrix substrate includes multiple data signal line connection wires that are disposed near a first end portion and multiple divided common electrode wire connection wires that are disposed near a second end portion. A distance between end portions of the multiple data signal line connection wires facing multiple data signal terminals is shorter than a distance between end portions of the multiple data signal line connection wires facing a pixel region. A distance between end portions of the multiple divided common electrode wire connection wires facing divided common electrode terminals is shorter than a distance between end portions of the multiple divided common electrode wire connection wires facing the pixel region.

Privacy cells can be configured to enable segmented control. A privacy cell can include a segmented array of electrodes that allow segments of liquid crystal to be independently controlled. By independently applying a voltage to each electrode, the liquid crystal within each segment can be independently oriented at a desired angle for a particular mode of operation.

A display device, including a substrate, a first transistor, a second transistor, a first pixel electrode, a second pixel electrode, and a common electrode layer, is provided. The first transistor and the second transistor are disposed on the substrate. The first pixel electrode is electrically connected to the first transistor. The second pixel electrode is electrically connected to the second transistor. The second pixel electrode is disposed adjacent to the first pixel electrode. The common electrode layer has a first slit. The first slit spans from the first pixel electrode to the second pixel electrode.

Privacy cells can be configured to enable segmented control. A privacy cell can include a segmented array of electrodes that allow segments of liquid crystal to be independently controlled. By independently applying a voltage to each electrode, the liquid crystal within each segment can be independently oriented at a desired angle for a particular mode of operation.

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.

An active matrix substrate includes multiple data signal line connection wires that are disposed near a first end portion and multiple divided common electrode wire connection wires that are disposed near a second end portion A distance between end portions of the multiple data signal line connection wires facing multiple data signal terminals is shorter than a distance between end portions of the multiple data signal line connection wires facing a pixel region. A distance between end portions of the multiple divided common electrode wire connection wires facing divided common electrode terminals is shorter than a distance between end portions of the multiple divided common electrode wire connection wires facing the pixel region.

An optical system with an electronically variable iris. The optical system comprises an optical lens. A number of transparent conductive layers is coupled to an optical surface of the optical lens. A liquid crystal film is separated into a number of portions by the number of transparent conductive layers, wherein a transmissive state of each portion, from the number of portions of the liquid crystal film, with respect to light is configured to change in response to application of a voltage to the number of transparent conductive layers.