A verifiable display is provided that enables the visual content of the display to be detected and confirmed in a variety of ambient lighting conditions, enviroments, and operational states. In particular, the verifiable display has a display layer that is capable of visually setting an intended message for human or machine reading, with the intendended message being set using pixels. Depending on the operational condition of the display and the ambient light, for example, the message that is actually displayed and perceivable may vary from the intended message. To detect what message is actually displayed, a light detection layer in the verifiable display detects the illumination state of the pixels, and in that way is able to detect what message is actually being presented by the display layer.

In one embodiment, a display device includes first and second substrates, a liquid crystal layer, a display area, a surrounding area, a light-shielding layer overlapping the surrounding area, a voltage supply line in the surrounding area and extending in a first direction, and first and second electrodes provided in the surrounding area and connected to the voltage supply line. The first and second electrodes are alternately arranged in either the first direction or a second direction crossing the first direction. Further, a first voltage supplied to the first electrode is different from a second voltage supplied to the second electrode.

In one embodiment, a display device includes first and second substrates, a liquid crystal layer, a display area, a surrounding area, a light-shielding layer overlapping the surrounding area, a voltage supply line in the surrounding area and extending in a first direction, and first and second electrodes provided in the surrounding area and connected to the voltage supply line. The first and second electrodes are alternately arranged in either the first direction or a second direction crossing the first direction. Further, a first voltage supplied to the first electrode is different from a second voltage supplied to the second electrode.

A novel circuit, a novel display portion, a novel display system, or the like is provided. A circuit, a display portion, a display system, or the like which has low power consumption is provided. A plurality kinds of video signals are generated by division of input data and supplied to different pixel groups. Thus, for example, the plurality of video signals can be supplied individually, and the operation states of a plurality of driver circuits can be controlled individually, leading to fine-grained operation with low power consumption. Accordingly, a decoder, a display portion, or a display system having low power consumption can be provided.

A novel circuit, a novel display portion, a novel display system, or the like is provided. A circuit, a display portion, a display system, or the like which has low power consumption is provided. A plurality kinds of video signals are generated by division of input data and supplied to different pixel groups. Thus, for example, the plurality of video signals can be supplied individually, and the operation states of a plurality of driver circuits can be controlled individually, leading to fine-grained operation with low power consumption. Accordingly, a decoder, a display portion, or a display system having low power consumption can be provided.

To display an image and the back side image in an overlapped state on a screen, with good visibility and see-through capability. The screen scanned with an image light from the projector has an optical layer and a plurality of control electrodes which are arranged side by side along the optical layer. The synchronous controller applies a voltage to the plurality of control electrodes, and, in a scanning period T of the image light, switches the optical state of the screen by the unit of the segmented region, between the visual state and the nonvisual state. The synchronous controller, in the period T, switches the optical state of a plurality of segmented regions 22 in synchronous with the scanning period of the image light, maintains the optical state of a projected region of the screen in the visual state by a voltage with two or more amplitudes.

To display an image and the back side image in an overlapped state on a screen, with good visibility and see-through capability. The screen scanned with an image light from the projector has an optical layer and a plurality of control electrodes which are arranged side by side along the optical layer. The synchronous controller applies a voltage to the plurality of control electrodes, and, in a scanning period T of the image light, switches the optical state of the screen by the unit of the segmented region, between the visual state and the nonvisual state. The synchronous controller, in the period T, switches the optical state of a plurality of segmented regions 22 in synchronous with the scanning period of the image light, maintains the optical state of a projected region of the screen in the visual state by a voltage with two or more amplitudes.

A display device employs a patterned quantum rod layer having pixel elements driven by pixel splitting to generate a privacy viewing mode. The display device includes a patterned quantum rod layer having first pixel elements including first quantum rods wherein the first quantum rods are aligned in a first alignment direction, and second pixel elements including second quantum rods wherein the second quantum rods are aligned in a second alignment direction different from the first alignment direction. An electronic controller is configured to perform pixel splitting whereby the electronic controller drives the first pixel elements and the second pixel elements such that the patterned quantum rod layer has an off-axis luminance different from an on-axis luminance to generate a privacy viewing mode. The first alignment direction may be oriented 90° relative to the second alignment direction.

An integrated circuit device includes a voltage supply circuit and a drive circuit. The voltage supply circuit supplies a common voltage, a first positive polarity voltage higher than the common voltage, a second positive polarity voltage higher than the first positive polarity voltage, a first negative polarity voltage lower than the common voltage, and a second negative polarity voltage lower than the first negative polarity voltage. The drive circuit outputs a first drive waveform signal for dot matrix display based on the common voltage, the first positive polarity voltage, the second positive polarity voltage, the first negative polarity voltage, and the second negative polarity voltage, and outputs a second drive waveform signal for segment display based on the common voltage, the first positive polarity voltage, and the first negative polarity voltage.

An integrated circuit device includes a voltage supply circuit and a drive circuit. The voltage supply circuit supplies a common voltage, a first positive polarity voltage higher than the common voltage, a second positive polarity voltage higher than the first positive polarity voltage, a first negative polarity voltage lower than the common voltage, and a second negative polarity voltage lower than the first negative polarity voltage. The drive circuit outputs a first drive waveform signal for dot matrix display based on the common voltage, the first positive polarity voltage, the second positive polarity voltage, the first negative polarity voltage, and the second negative polarity voltage, and outputs a second drive waveform signal for segment display based on the common voltage, the first positive polarity voltage, and the first negative polarity voltage.