Techniques for encapsulating video streams containing multiple coded views in a media file are described herein. In one example, a method includes parsing a track of multiview video data, wherein the track includes at least one depth view. The method further includes parsing information to determine a spatial resolution associated with the depth view, wherein decoding the spatial resolution does not require parsing of a sequence parameter set of the depth view. Another example method includes composing a track of multiview video data, wherein the track includes the one or more views. The example method further includes composing information to indicate a spatial resolution associated with the depth view, wherein decoding the spatial resolution does not require parsing of a sequence parameter set of the depth view.

Techniques for encapsulating video streams containing multiple coded views in a media file are described herein. In one example, a method includes parsing a track of multiview video data, wherein the track includes at least one depth view. The method further includes parsing information to determine a spatial resolution associated with the depth view, wherein decoding the spatial resolution does not require parsing of a sequence parameter set of the depth view. Another example method includes composing a track of multiview video data, wherein the track includes the one or more views. The example method further includes composing information to indicate a spatial resolution associated with the depth view, wherein decoding the spatial resolution does not require parsing of a sequence parameter set of the depth view.

Techniques for encapsulating video streams containing multiple coded views in a media file are described herein. In one example, a method includes parsing a track of multiview video data, wherein the track includes at least one depth view. The method further includes parsing information to determine a spatial resolution associated with the depth view, wherein decoding the spatial resolution does not require parsing of a sequence parameter set of the depth view. Another example method includes composing a track of multiview video data, wherein the track includes the one or more views. The example method further includes composing information to indicate a spatial resolution associated with the depth view, wherein decoding the spatial resolution does not require parsing of a sequence parameter set of the depth view.

Techniques for encapsulating video streams containing multiple coded views in a media file are described herein. In one example, a method includes parsing a track of multiview video data, wherein the track includes at least one depth view. The method further includes parsing information to determine a spatial resolution associated with the depth view, wherein decoding the spatial resolution does not require parsing of a sequence parameter set of the depth view. Another example method includes composing a track of multiview video data, wherein the track includes the one or more views. The example method further includes composing information to indicate a spatial resolution associated with the depth view, wherein decoding the spatial resolution does not require parsing of a sequence parameter set of the depth view.

An image capturing apparatus that continuously generates and records a sequence of RAW images, the image capturing apparatus comprising, an image capturing unit configured to generate a RAW image by shooting a subject, an encoding unit configured to generate encoded data by encoding the RAW image, and a recording/reproduction unit configured to record the encoded data in a recording medium and read out the encoded data from the recording medium, wherein the encoding unit includes a quantization unit configured to, when the sequence of RAW images are continuously generated, perform quantization while changing a quantization parameter within the same RAW image.

An image capturing apparatus that continuously generates and records a sequence of RAW images, the image capturing apparatus comprising, an image capturing unit configured to generate a RAW image by shooting a subject, an encoding unit configured to generate encoded data by encoding the RAW image, and a recording/reproduction unit configured to record the encoded data in a recording medium and read out the encoded data from the recording medium, wherein the encoding unit includes a quantization unit configured to, when the sequence of RAW images are continuously generated, perform quantization while changing a quantization parameter within the same RAW image.

An optical system for capturing an image using compressive sensing includes: a digital micromirror device (DMD) array; an optical lens system; a first optical detector array; a first optical channel for projecting spatial information onto the first detector array; a second optical detector array; a second optical channel; a spectral filter and a polarization filter for projecting spectral and polarization information onto the second detector array; and an image processor to control the DMD array to generate a first and a second set of samples of the image using a sampling rate lower than required by the Shannon-Nyquist sampling theorem, and to reconstruct the image from the samples collected and digitized by the first and second optical detector arrays.

An optical system for capturing an image using compressive sensing includes: a digital micromirror device (DMD) array; an optical lens system; a first optical detector array; a first optical channel for projecting spatial information onto the first detector array; a second optical detector array; a second optical channel; a spectral filter and a polarization filter for projecting spectral and polarization information onto the second detector array; and an image processor to control the DMD array to generate a first and a second set of samples of the image using a sampling rate lower than required by the Shannon-Nyquist sampling theorem, and to reconstruct the image from the samples collected and digitized by the first and second optical detector arrays.

Disclosed is an electronic device including a memory that stores at least one command associated with an image encoding and a processor electrically connected to the memory. The command executed while the processor is operated divides a content generation buffer allocated in association with a specified content generation into a plurality of partial areas, stitches a previous image and a present image with respect to at least a portion of an area in which the present image overlaps with the previous image, and performs a parallel encoding on each of the partial areas of the stitched images in a specified block size when the stitched images are stored in the content generation buffer.

Disclosed is an electronic device including a memory that stores at least one command associated with an image encoding and a processor electrically connected to the memory. The command executed while the processor is operated divides a content generation buffer allocated in association with a specified content generation into a plurality of partial areas, stitches a previous image and a present image with respect to at least a portion of an area in which the present image overlaps with the previous image, and performs a parallel encoding on each of the partial areas of the stitched images in a specified block size when the stitched images are stored in the content generation buffer.