A display device can include a first display configured to produce an image and a plurality of transparent displays. Each of the plurality of transparent displays can be configured to produce a slice of the image to provide depth and a three-dimensional effect to the image, or at least one of the plurality of transparent displays can be configured to block, diffuse, or scatter light associated with the image produced by the first display so that different ones of a plurality of users see different content derived from the image produced by the first display. Each of the transparent displays can be substantially transparent. Further, at least one of the plurality of transparent displays can be made using Smectic A liquid crystals.

Hand gestures may be performed to control a visual projector. When a human hand is placed into a projection field of the visual projector, the visual projector responds to hand gestures performed by the human hand. The human hand, for example, may gesture to rotate a projected image or to correct the projected image. The visual projector may thus manipulate and/or correct the projected image in response to the gesture performed by the human hand.

The present invention concerns the field of stereoscopic vision systems and more particularly the management of the position of the focal plane in a stereoscopic scene. The invention aims to propose a method for managing the focal plane within a stereoscopic image or a sequence of stereoscopic images. A translation of the right and left images is effected in order to place the focal plane in front of the scene viewed. Advantageously, the depth of the major objects of the scene is estimated by a division of the images into a plurality of zones and estimation of the depth of each of the zones. The depth of the focal plane is then calculated so that most of the scene is behind the focal plane.

In an image processing apparatus, an image pickup unit takes images of an object including the face of a person wearing the glasses by which to observe a stereoscopic image that contains a first parallax image and a second parallax image obtained when the object in a three-dimensional (3D) space is viewed from different viewpoints. A glasses identifying unit identifies the glasses included in the image of the object taken by the image pickup unit. A face detector detects a facial region the face of the person included in the image of the object taken by the image pickup unit, based on the glasses identified by the glasses identifying unit. An augmented-reality special rendering unit adds a virtual feature to the facial region of the face of the person detected by the face detector.

An autostereoscopic display device comprises a display arrangement such as an emissive display arrangement or an reflective display arrangement, with an array of spaced pixels. A light guiding arrangement has an array of light guide columns, with one column over each display pixel or over a group (such as a column) of pixels. The light guide columns comprise aside wall which tapers outwardly to define a funnel shape with the pixel at the smaller base of the funnel. The funnel provides collimation to reduce cross talk in the display, which is particularly problematic for 3D autostereoscopic displays.

An apparatus and method generate a three-dimensional image by presenting, using a stereoscopic display, a representation of a scene comprising one or more objects, tracking a gaze of the user to determine a direction of gaze within the scene, determining depths associated with one or more objects in the scene, and determining which of the objects in the scene are inside and which are outside a comfort zone based at least in part on the direction of gaze of the user and the depths associated with the one or more objects in the scene. In some embodiments, the method includes identifying one or more objects proximate the direction of gaze of the user, determining depths associated with the one or more identified objects, determining a range of depths based at least in part on the depths associated with the one or more identified objects, and establishing the comfort zone based at least in part on the range of depths. In some embodiments, the method includes modifying the presented representation of the scene based on which of the objects are outside the comfort zone. In some embodiments, the method includes focusing the stereoscopic display based at least in part on the determination of which objects are inside the comfort zone, tracking the gaze of the user to determine a second direction of gaze within the scene different from the direction of gaze within the scene, re-determining depths associated with one or more objects in the scene, re-determining which of the objects in the scene are inside and which are outside the comfort zone based at least in part on the second direction of gaze of the user and the re-determined depths associated with the one or more objects in the scene, and re-focusing the stereoscopic display based at least in part on the determination of which objects are inside the comfort zone.

A system and methods for visualizing information on a generally large scale. Certain embodiments include display elements that include a minimized border margin, 2D/3D dual functionality, and ultra-high resolution. The display elements may be positioned relative to an infrastructure element configured to permit generating a wide variety of display geometries.

Provided is an image display device used by being mounted to a head or a face of a user, including a first display unit that displays an internal image seen from a side of the user, a second display unit that displays an external image seen from outside the image display device, and a control unit that controls display of the internal image and the external image.

According to one of aspects, a display device includes: a display unit configured to stereoscopically display an aggregation configured from a plurality of regular hexahedrons arrayed along mutually perpendicular three directions, in a display space, by displaying images respectively corresponding to both eyes of a user by being worn; a detection unit configured to detect movement of a body in the display space; and a control unit configured to change positions of the regular hexahedrons of the aggregation according to a detection result of the detection unit. Each of six faces of the aggregation includes external faces of the regular hexahedrons as elements, and notations with which whether all of the elements on the same face of the aggregation belong to a same group is discriminative are provided to the respective elements.

A system for distributing auto-stereoscopic images, a parallax blocking mask and methods for producing a parallax blocking mask. A parallax blocking mask is provided as an “add-on” for an existing image display device having a flat panel type display screen. The mask is tailored to the needs of the existing device and delivered to a remote user of the display device. The user mounts the mask to the display device so that the mask overlies the display screen. 3D content in the form of composite stereoscopic images derived from one or more stereoscopic image pairs, and application software, are downloaded to the display device over the Internet, and the application software interleaves the composite stereoscopic images for display on the display screen while the mask is in place. Use of a parallax blocking mask having variable edge transitions, a duty cycle less than fifty percent, or both, is disclosed.