A non-transitory three-dimensional image signal includes a first image component, a second component for creating a three-dimensional image in combination with the first image component, and a text component that includes text-based subtitles and/or presentation graphics-based bitmap images for including in the three-dimensional image. A shared Z-location component includes Z-location information describing the depth location of the text component within the three-dimensional image. The signal is rendered by rendering the three-dimensional image from the first image component and the second component. The rendering includes rendering the text-based subtitles and/or presentation graphics-based bitmap images in the three-dimensional image. Further, the rendering of the text component includes adjusting the depth location of the text-based subtitles and/or presentation graphics-based bitmap images based on the shared Z-location component. The Z-location for both text-based and presentation-graphics-based subtitles may be the same and only needs to be stored once per stream.

The invention relates to an image processing device and an image processing method capable of collectively encoding a color image and a depth image of different resolutions. The image processing device comprising an image frame converting unit that converts the resolution of the depth image to the same resolution as that of the color image. An additional information generating unit that generates additional information including information to specify the color image, or information to specify the depth image, image frame conversion information indicating an area of a black image included in the depth image, the resolution of which is converted, and resolution information to distinguish whether the resolutions of the color image and the depth image are different from each other. This technology may be applied to the image processing device of images of multiple viewpoints.

A single image sensor including an array of uniformly and continuously spaced light-sensing pixels in conjunction with a plurality of lenses that focus light reflected from an object onto a plurality of different pixel regions of the image sensor, each lens focusing light on a different one of the pixel regions enables a controller, including a processor and an object detection module, coupled to the single image to analyze the pixel regions, to generate a three-dimensional (3D) image of the object through a plurality of images obtained with the image sensor, generate a depth map that calculates depth values for pixels of at least the object, detect 3D motion of the object using the depth values, create a 3D model of the object based on the 3D image, and track 3D motion of the object based on the 3D model.

To provide an image capture device capable of doing multiple image captures by using multiple image capture units and capable of measuring a distance between each of the image capture units and a target more correctly. An image capture device according to the present invention is an image capture device with multiple image capture units. The image capture device comprises: one light emission unit for distance measurement that emits a reference beam; and the multiple image capture units that capture images of a reflected beam of the reference beam while having common timing of image capture.

A 3D imaging apparatus with enhanced depth of field to obtain electronic images of an object for use in generating a 3D digital model of the object. The apparatus includes a housing having mirrors positioned to receive an image from an object external to the housing and provide the image to an image sensor. The optical path between the object and the image sensor includes an aperture element having apertures for providing the image along multiple optical channels with a lens positioned within each of the optical channels. The depth of field of the apparatus includes the housing, allowing placement of the housing directly on the object when obtaining images of it.

An electronic device is provided. The electronic device includes a memory configured to store an image of a multi-field of view (multi-FOV) including an image of a first FOV and an image of a second FOV, a display configured to output the image of the multi-FOV, and a processor configured to be electrically connected with the memory and the display. The process is configured to control to output the image of the first FOV on the display, verify at least one event which meets a condition from the image of the second FOV, and control to provide a notification corresponding to the event in connection with the image of the first FOV, the image being output on the display.

An apparatus for processing 3-Dimensional (3D) broadcast signals, comprises: a tuner for receiving broadcast signals containing 3D content; a service information processor for parsing target viewing information and at least one reference viewing condition information received from the broadcast signals which are received; a viewing analysis module for receiving viewing condition information of the viewer, parsing compensation-type information that is included in the reference viewing condition information, which contains information that is most relevant to the viewing condition information that is received, and for rendering the 3D content so that an element expressed by the correction-type information is maintained; and an output formatter for controlling so that the 3D content that is rendered is displayed.

The method for transmitting an image component for a 3D image according to one embodiment of the present invention comprises: a step of generating one or more texture image components and one or more depth map image components; a step of generating an SEI (supplemental enhancement information) message including a 3D layer information element for signaling layer information relating to coding between said one or more texture image components and one or more depth map image components; a step of generating an NAL unit including the SEI message including said 3D layer information element; and a step of generating a broadcast signal including said one or more texture image components, said one or more depth map image components and the NAL unit.

An active-pulsed four-dimensional camera system that utilizes a precisely-controlled light source produces spatial information and human-viewed or computer-analyzed images. The acquisition of four-dimensional optical information is performed at a sufficient rate to provide accurate image and spatial information for in-motion applications where the camera is in motion and/or objects being imaged, detected and classified are in motion. Embodiments allow for the reduction or removal of image-blocking conditions like fog, snow, rain, sleet and dust from the processed images. Embodiments provide for operation in daytime or nighttime conditions and can be utilized for day or night full-motion video capture with features like shadow removal. Multi-angle image analysis is taught as a method for classifying and identifying objects and surface features based on their optical reflective characteristics.

A privacy camera, such as a light field camera that includes an array of cameras or an RGBZ camera(s)) is used to capture images and display images according to a selected privacy mode. The privacy mode may include a blur background mode and a background replacement mode and can be automatically selected based on the meeting type, participants, location, and device type. A region of interest and/or an object(s) of interest (e.g. one or more persons in a foreground) is determined and the privacy camera is configured to clearly show the region/object of interest and obscure or replace the background according to the selected privacy mode. The displayed image includes the region/object(s) of interest clearly shown (e.g. in focus) and any objects in a background of the combined image shown having a limited depth of field (e.g. blurry/not in focus) and/or the background replaced with another image and/or fill.