An image display device includes a display panel, a barrier panel, and a controller. The display panel is configured to be able to form a first display region, to be able to display a right-eye image in a right-eye visible region of the first display region and display a left-eye image in a left-eye visible region of the first display region. The barrier panel is configured to be able to form a first barrier region and to form a light-transmitting portion and a dimming portion in the first barrier region. The controller is configured to display a portion located in the first display region as one parallax image frame including two sub-frames. The controller is configured to form the dimming region in the entire first barrier region during a frame change period including a timing of changing a display from the parallax image frame to a new parallax image frame.

A display device includes: a first panel including a first image-forming surface for forming a first image visually recognized by a user and a plurality of first pixels; a second panel including a second image-forming surface for forming a second image visually recognized by the user and a plurality of second pixels; and a half-wavelength plate located between the first image-forming surface and the second image-forming surface. The half-wavelength plate includes an optical axis, is configured to be capable of transmitting incident light from either one panel of the first panel and the second panel, and of emitting light as emission light to the other panel. A polarization direction of the emission light from the half-wavelength plate is determined based on a polarization direction of the incident light on the half-wavelength plate and a direction of the optical axis.

An information display device includes a light emitting panel, a shutter panel, and a controller. The light emitting panel includes a plurality of transmitting portions configured to transmit first light and a plurality of light emitting portions configured to emit second light. The transmitting portions and the light emitting portions are configured to be alternately arranged along a predetermined direction including a component in a direction in which a first eye and a second eye of a user are arranged. The shutter panel is configured to be positioned to be overlapped with the light emitting panel and includes a dimming region which is capable of operating so that the first light and the second light are reduced. The controller is capable of controlling the dimming region so that the first light enters the first eye and the second light enters the second eye.

A multiview backlight includes a first array active emitters configured to provide a first plurality of directional light beams and a second array of active emitters configured to provide a second plurality of directional light beams. The second array of active emitters is interleaved between active emitters of the first array of active emitters. Further, directional light beams of each of the first and second directional light beam pluralities have directions corresponding to view directions of a multiview display. A multiview display further includes an array of light valves configured to modulate the directional light beams to display a multiview image. An image resolution of the multiview image is configured to be dynamically selectable according to operational mode.

A system and method to dynamically control a configuration of parallax barriers includes performing skeletal tracking, using a skeletal tracking system, to determine a position of each viewer of content displayed by an image source. One of the parallax barriers among the parallax barriers is determined as being most closely associated with a viewing angle of each viewer, and the one of the parallax barriers is adjusted as needed to display the content as a three-dimensional image to one or more of the viewers with the viewing angle that is the most closely associated.

A system and method to dynamically control a configuration of parallax barriers includes performing skeletal tracking, using a skeletal tracking system, to determine a position of each viewer of content displayed by an image source. One of the parallax barriers among the parallax barriers is determined as being most closely associated with a viewing angle of each viewer, and the one of the parallax barriers is adjusted as needed to display the content as a three-dimensional image to one or more of the viewers with the viewing angle that is the most closely associated.

A multiview backlight and a multiview display employ active emitters configured to provide a plurality of light beams having different principal angular directions corresponding to different view directions of the multiview display. A size of the active emitter is comparable to a size of a view pixel in the multiview display. A distance between active emitters is commensurate with a distance between adjacent multiview pixels of the multiview display. A multiview display further includes an array of light valves configured to modulate the directional light beams to display a multiview image.

A head-up display includes a first panel, a second panel, and an optical system. The first panel includes first subpixels arranged at a first pitch in a parallax direction, in which direction binocular parallax is provided to user's eyes. The second panel includes second subpixels arranged at a second pitch in the parallax direction. The second panel is placed along the first panel. The second panel is configured to produce, based on an image displayed on the first panel, a parallax image for providing binocular parallax to the user's eyes. The optical system enables the parallax image to be provided in enlarged dimension to the user's eyes. The first pitch and the second pitch are equal to each other.

A liquid crystal (LC) device includes an optical stack arrangement including from the viewing side: a first electrode component; a first LC alignment layer; an LC layer; a second LC alignment layer; and a second electrode component. A voltage is applied to the LC device to create a potential difference between the first and second electrode components to switch an alignment of liquid crystals of selected portions of the LC layer from a first state when no voltage is applied to a second state when the voltage is applied. The first and second LC alignment layers are vertical alignment layers that induce a vertical alignment of the liquid crystals such that the first state when no voltage is applied is a vertical alignment state, and the liquid LC crystals switch to a planar alignment state as the second state when the voltage is applied. The first and/or second electrode components is a dual layer segmented electrode component comprising a first layer of electrode elements separated by inter-electrode gaps and a second layer of electrode elements separated by inter-electrode gaps, the first layer of electrode elements and the second layer of electrode elements being spaced apart in a viewing direction by an insulator layer.

A light source, a light source assembly, a display device and a display method. The light source comprises a first light emitting region and a second light emitting region. The first light emitting region and the second light emitting region can control ON or OFF of the light emission separately. The first light emitting region and the second light emitting region are arranged alternately along a first direction. The first light emitting region and the second light emitting region of the light sources in this disclosure can be controlled separately. Hence, one light emitting region can be made to emit light while the other light emitting region can be made to be turned off. There is no stray light in the turned-off light emitting region, so as to avoid stray light crosstalk to light of the other light emitting region.