A 2D/3D conversion processing section converts 2D contents (television broadcast program) received by a television broadcast receiving section to contents for the right eye and contents for the left eye for 3D, and the contents for 3D obtained by conversion are subjected to 3D display on a display section. When switching is made from 2D display to 3D display, a central control section suppresses display of data-broadcast data regarding television video data. Consequently, even if video display of the television broadcast is switched from 2D to 3D, video of television broadcast can be displayed in 3D as effectively as possible.

A method of operation of three dimensional (3D) stereoscopic television consistent with certain implementations involves turning on or installing a set of 3D glasses on a viewer to cause the set of 3D glasses to enter an active operational mode; and at the 3D glasses, emitting a signal to the television that causes the television to switch from a 2D display mode to a 3D display mode. This abstract is not to be considered limiting, since other embodiments may deviate from the features described in this abstract.

In a digital contents receiver for receiving transmitted digital contents, the digital contents include at least component information indicating an element which constitutes a program of the contents. When the component information indicates that the received digital contents are a 3D component, it is determined whether a display part corresponds to display of the 3D component. If the display part corresponds to display of the 3D component, the received digital contents are displayed in 3D.

A display device capable of displaying both a 3D image and a 2D image is provided. The display device includes a plurality of optical filter regions where light-blocking panels for producing binocular disparity are arranged in matrix. The light-blocking panel can select whether to transmit light emitted from a display panel in each of the plurality of optical filter regions. Thus, in the display device, some regions where binocular disparity is produced can be provided. Consequently, the display device can display both a 3D image and a 2D image.

A display device includes: a first substrate and a second substrate; and a plurality of pixel portions provided between the first substrate and the second substrate, wherein the second substrate includes a plurality of lenticular lens portions, and each of the plurality of lenticular lens portions includes: a curved portion corresponding to a first pixel portion among the plurality of pixel portions; and a plane portion corresponding to a second pixel portion that neighbors the first pixel portion among the plurality of pixel portions.

A broadcast receiver and a method for processing video data are disclosed. The method for controlling a three dimensional (3D) video display output of a broadcast receiver includes receiving a broadcast signal including a video stream, wherein the video stream includes a plurality of video stream sections having different view points, acquiring view point information indicating corresponding view points of the video stream sections, and controlling a three dimensional (3D) video display output of the video stream according to the obtained view point information.

A switchable autostereoscopic display device includes a display panel having an array of display pixels for producing a display, and a lens arrangement for directing the output from different pixels to different spatial positions to enable a stereoscopic image to be viewed. The lens arrangement is in a plane parallel to the display panel and includes an electrically switchable LC layer which defines a lens pattern or a lens replica pattern. The LC alignment of the LC layer is electrically switchable such that the lens arrangement is switchable between 2D and 3D modes. In the 2D mode, the LC alignment is in a first direction substantially within the plane of the lens arrangement; and in the 3D mode, the LC alignment is in a second, perpendicular direction also substantially within the plane of the lens arrangement. The light output of the display panel is polarized in the second direction.

A stereoscopic display device comprising: a stereoscopic display unit; a space sensor; a determination unit for determining whether the instruction position detected by the space sensor is within a detection area corresponding to the instruction stereoscopic image, and accepting an instruction corresponding to the instruction stereoscopic image; a disparity amount decision unit for deciding a disparity amount between the instruction left-eye image and the instruction right-eye image displayed by the stereoscopic display unit, and decreasing the disparity amount between the instruction left-eye image and the instruction right-eye image according to a decrease in the interval detected by the space sensor; and an image processing unit for displaying the instruction stereoscopic image on the stereoscopic display unit by the disparity amount decided by the disparity amount decision unit.

In a digital contents receiver for receiving transmitted digital contents, the digital contents include at least component information indicating an element which constitutes a program of the contents. When the component information indicates that the received digital contents are a 3D component, it is determined whether a display part corresponds to display of the 3D component. If the display part corresponds to display of the 3D component, the received digital contents are displayed in 3D.

In a digital contents receiver for receiving transmitted digital contents, the digital contents include at least component information indicating an element which constitutes a program of the contents. When the component information indicates that the received digital contents are a 3D component, it is determined whether a display part corresponds to display of the 3D component. If the display part corresponds to display of the 3D component, the received digital contents are displayed in 3D.