A video display device includes performs a first Retinex process on an inputted video and a second Retinex process, which is different from the first Retinex process, on the inputted video. A video composing unit is configured to compose a video processed by the first Retinex processing unit and a video processed by the second Retinex processing unit in accordance with a feature of the inputted video, which is then displayed. In a process of composing the video processed by the first and second Retinex processing units, the video composing unit is configured to perform a process of converting a luminance level for each pixel so that more output luminance levels are assigned to a luminance band having a large frequency distribution to improve visibility of the video. A gain of the luminance level converting process is varied in accordance with an average pixel value level of the inputted video.

Videos are to be displayed in parallel, without missing information or a decrease in efficiency in the usable display region.

The aspect ratio of the large screen of an information processing apparatus 100 is 16:9, which is compatible with a Hi-Vision video. In a case where the large screen is used in a portrait layout, if the large screen is divided into three small screens in the vertical direction, the aspect ratio of the small screens after the dividing is 9:16/3=16:9.48. With respect to the original video content at 16:9, the ratio in inches is 9/16=56.25% (the area ratio is (9/16).sup.2=31.64%). Accordingly, the usable display region can be efficiently used.

An information processing device (1) according to an embodiment includes a display control unit (34) and a decision unit (31). The display control unit (34) displays a content image on a head-mounted display. During display of the content image by the display control unit (34), the decision unit (31) decides whether or not a surrounding person exists in a front direction of the head-mounted display on the basis of a camera image obtained by capturing an image of a surrounding environment of the head-mounted display. In a case where the decision unit (31) decides that a surrounding person exists, the display control unit (34) moves a display position of the content image.

[Object] To provide a display apparatus, an image generation method, and a program that are capable of displaying images such that an image displayed on a display unit and a scene outside the display apparatus appear to be continuous.

[Solving Means] The display apparatus includes a first image sensor, a first distance sensor, a second sensor, a display unit, and an image generation unit. The first image sensor is disposed on a first surface side of an apparatus main body. The first distance sensor is disposed on the first surface side. The second sensor is disposed on a second surface side opposite to the first surface side. The display unit is disposed on the second surface side. The image generation unit generates a display image to be displayed on the display unit, using a two-dimensional image of a subject and a distance image of the subject, the two-dimensional image being acquired by the first image sensor, the distance image being acquired by the first distance sensor, on the basis of three-dimensional position information of a viewpoint of a photographer, the three-dimensional position information being calculated on the basis of a sensing result acquired by the second sensor.

Configuration of a multi-display system is facilitated by use of general television receivers (display devices). Multiple digital interface terminals to which each of multiple display devices configuring a multi-display is connected via a transmission path are provided. A video signal is output to each of the multiple digital interface terminals. Replacement of the video signals output from the signal output unit to the multiple digital interface terminals is controlled to display a correct video corresponding to each screen of the multi-display. For example, the replacement of the video signals is controlled according to a video replacement operation signal sent from any of the multiple display devices via the transmission path.

Provided is a display apparatus including a screen portion in which unit panels in which a plurality of pixels formed from light-emitting elements is disposed are arranged, in which a first pixel-to-pixel pitch that is a space between two outer end pixels adjacent to each other across outer peripheries of the unit panels is equal to or larger than a second pixel-to-pixel pitch that is a space between each of the outer end pixels in each of the unit panels and a pixel adjacent to the outer end pixel, and the pixel-to-pixel pitches adjacent to each other in the array of the pixel-to-pixel pitches in a direction in which the first pixel-to-pixel pitch and the second pixel-to-pixel pitch are arranged in the unit panel are set to be P(in)≤P(out) where P(in) denotes the pixel-to-pixel pitch located on a central side of the unit panel and P(out) denotes the pixel-to-pixel pitch located on an outer peripheral side of the unit panel.

This imaging signal processing apparatus includes: a first video signal processing unit that generates, from a pixel signal obtained by an imaging unit capable of obtaining a pixel signal with a first dynamic range, a luminance reduction video signal with a second dynamic range narrower than the first dynamic range; and a second video signal processing unit that generates, from the pixel signal, an information signal of a luminance change component of a luminance region of the luminance reduction video signal and a gain up signal of a pixel signal of the luminance region and adds the information signal and the gain up signal to the luminance reduction video signal.

The present technology relates to an information processing device, an information processing method, a program, and a movable object that enable prevention of a user from suffering from motion sickness. The information processing device includes: a display-position setting unit configured to move, on the basis of the motion of a movable object, the display position of a first picture viewed from a predetermined point of view of the movable object; and a display control unit configured to perform display control based on the display position set. The present technology can be applied to, for example, a vehicle that displays a picture in superimposition on the ambient scenery.

A display for displaying a wide Field of View (FoV) scene including a holographic image within the scene, including a first Spatial Light Modulator (SLM) and an optical system for producing a first holographic image at a center of a displayed scene, and a second image display for producing at least a first additional image adjacent to the first holographic image. In some embodiments an augmented reality display is used for the displaying of the first holographic image at the center of a field of view and the second image adjacent to the first holographic image. In some embodiments a virtual reality display is used for the displaying of the first holographic image near the center of a field of view and the second image adjacent to the first holographic image. Related apparatus and methods are also described.

A display for displaying a wide Field of View (FoV) scene including a holographic image within the scene, including a first Spatial Light Modulator (SLM) and an optical system for producing a first holographic image at a center of a displayed scene, and a second image display for producing at least a first additional image adjacent to the first holographic image. In some embodiments an augmented reality display is used for the displaying of the first holographic image at the center of a field of view and the second image adjacent to the first holographic image. In some embodiments a virtual reality display is used for the displaying of the first holographic image near the center of a field of view and the second image adjacent to the first holographic image. Related apparatus and methods are also described.