Abstract: The present invention relates to a technique for encoding and decoding an image, and a method for encoding the image, according to the present invention, comprises the steps of: performing a prediction with respect to a current block; and transforming a residual which is generated by the prediction, wherein in the step of transforming, a first transform is performed on the residual, and then a second transform is performed on a lower frequency area, and wherein a mode of the second transform can be decided on the basis of a mode of the first transform.

Abstract: Aspects of the present disclosure provide an image processing device that includes circuitry configured to perform a decoding process on an encoded stream for generating an image. The encoded stream is arranged into largest coding units (LCUs), and filtering parameters applicable to each LCU are provided at a beginning portion of the corresponding LCU. The circuitry is further configured to perform adaptive offset filtering on portions of the image that correspond to the LCUs using the filtering parameters set at the beginning portions of the LCUs, respectively.

Abstract: An inter prediction method performed by a decoding apparatus includes: receiving information on a motion vector difference (MVD) in units of integer samples; deriving a first motion vector predictor (MVP) in units of fraction samples on the basis of neighboring blocks of a current block; deriving a second MVP in units of integer samples on the basis of the first MVP; determining a first motion vector (MV) in units of integer samples for the current block on the basis of the second MVP and the MVD; determining a second MV in units of fraction samples for the current block on the basis of the first MVP and the first MV; and generating a prediction sample for the current block on the basis of the second MV. The present invention is capable of increasing the accuracy of the MV while reducing the amount of data allocated to the MVD.

Abstract: The present inventive concepts discloses methods, apparatuses, and/or systems for enabling spatially varying auto focusing of one or more objects using an image capturing system. The methods, apparatuses, and/or systems may include focusing objects in a region of interest using lenses, enabling spatially varying auto focusing of objects in the region of interest using a spatial light modulators (SLM), which are out of focus in the region of interest, and capturing the focused and the auto focused objects in the region of interest using a camera sensor.

Abstract: Post-processing in a lidar system may be guided by camera information as described herein. In one embodiment, a camera system has a camera to capture images of the scene. An image processor is configured to classify an object in the images from the camera. A lidar system generates a point cloud of the scene and a modeling processor is configured to correlate the classified object to a plurality of points of the point cloud and to model the plurality of points as the classified object over time in a 3D model of the scene.

Abstract: A predictive coding system performs predictive encoding by determination of an optimum prediction mode from prediction methods for a pixel signal of a target block. A predicted signal is generated according to the determined mode, and a residual signal is determined. The residual signal and the optimum prediction mode are encoded to generate a compressed signal, which is decoded. The decoded signal is stored as a reconstructed picture sample. During encoding, a candidate prediction mode list is generated that contains elements of optimum prediction modes of previously-reproduced blocks neighboring the target block. A flag indicating whether the list contains an element corresponding to the optimum prediction mode is encoded, and an index to the corresponding element is encoded if the corresponding element is included in the list. The optimum prediction mode can be encoded based on identifying the elements in the list, unless no corresponding element appears on the list.

Abstract: A predictive coding system performs predictive encoding by determination of an optimum prediction mode from prediction methods for a pixel signal of a target block. A predicted signal is generated according to the determined mode, and a residual signal is determined. The residual signal and the optimum prediction mode are encoded to generate a compressed signal, which is decoded. The decoded signal is stored as a reconstructed picture sample. During encoding, a candidate prediction mode list is generated that contains elements of optimum prediction modes of previously-reproduced blocks neighboring the target block. A flag indicating whether the list contains an element corresponding to the optimum prediction mode is encoded, and an index to the corresponding element is encoded if the corresponding element is included in the list. The optimum prediction mode can be encoded based on identifying the elements in the list, unless no corresponding element appears on the list.

Abstract: Methods to improve the quality of coding high-dynamic range (HDR) signals are presented. Instead of using a single chroma quantization table for all color formats, a video encoder may adaptively use separate tables for each one, and transmit the table's ID to a decoder. Examples for chroma quantization tables for video content encoded in the YCbCr (PQ) and ICtCp (PQ) color formats under a variety of color gamut containers are provided.

Abstract: There is provided an image processing device including a decoding section that decodes an encoded stream and generates quantized transform coefficient data, and an inverse quantization section that, taking transform coefficient data as transform units to be used during inverse orthogonal transform, inversely quantizes the quantized transform coefficient data decoded by the decoding section, such that in a case where a non-square transform unit is selected, the inverse quantization section uses a non-square quantization matrix, corresponding to a non-square transform unit, that is generated from a square quantization matrix corresponding to a square transform unit.

Abstract: A stereoscopic image display can include an optical cell and a display panel including pixels defined by first and second short sides extended in a first direction, and first and second long sides extended in a second direction perpendicular to the first direction; and apertures defined by first and second sides parallel to the first long side, and third and fourth sides parallel to each other, in which the third side is inclined with a first predetermined angle between the first short side and the third side, the fourth side is inclined with a second predetermined angle between the first long side and the third side, a ratio of a length of the first short side to a length of the first long side is 1:2, and a ratio of a length of the first side to a length of the first long side is 1:2.

Abstract: A surveillance system including a video wall is provided. The surveillance system includes a plurality of video decoders configured to connect to the plurality of monitors in a one-to-one correspondence, respectively determine at least one image among a plurality of images based on first information, respectively receive an image-allocation area of the at least one image based on second information, the plurality of images respectively being provided from a plurality of cameras, and respectively input the image-allocation area to the plurality of monitors according to the one-to-one correspondence; and a video wall controller configured to provide each of the plurality of video decoders with the first information indicating at least one camera corresponding to the at least one image and the second information indicating an image-allocation area of the at least one image based on an entire video wall image.

Abstract: A predictive coding system performs predictive encoding by determination of an optimum prediction mode from prediction methods for a pixel signal of a target block. A predicted signal is generated according to the determined mode, and a residual signal is determined. The residual signal and the optimum prediction mode are encoded to generate a compressed signal, which is decoded. The decoded signal is stored as a reconstructed picture sample. During encoding, a candidate prediction mode list is generated that contains elements of optimum prediction modes of previously-reproduced blocks neighboring the target block. A flag indicating whether the list contains an element corresponding to the optimum prediction mode is encoded, and an index to the corresponding element is encoded if the corresponding element is included in the list. The optimum prediction mode can be encoded based on identifying the elements in the list, unless no corresponding element appears on the list.

Abstract: An imaging apparatus is provided. The imaging apparatus includes an imager configured to record an external image, a region determiner configured to divide a recorded previous image frame and a recorded current image frame into pluralities of regions, calculate a moving direction and a distance of each of the plurality of regions in the current image frame corresponding to each of the plurality of regions in the previous image frame, and determine a background and an object by applying a preset background model and object model based on the calculated moving direction and distance, and a posture determiner configured to determine body parts of the determined object based on a body part model, and determine a posture of the object by combining the determined body parts.

Abstract: A cellular phone and personal protective equipment usage system comprises a camera for detecting a person within an environment and a processor which receives information detected by the camera and determines whether the person is involved in distracting activities such as using a cellular phone or other portable electronic device, or print media, or is using personal protective equipment, and issues an alarm signal upon determining that the person is using a cellular phone or is not using personal protective equipment. The camera may be provided on or within a vehicle and the person is an operator of the vehicle. Alternatively, the camera may be mounted in a stationary location within a working site.

Abstract: The invention relates to a stereoscopic reproduction system without glasses, comprising an image reproduction device using transparency acting as means for illuminating multiple viewers with polarized light, two image capture elements separated from one another, containing polarizing filters that allow each of them to capture two images, one with the reflection of the light in the corneas and the other one eliminating said reflection, processing means for obtaining the pixel-by-pixel subtraction of those two images, the location of each eye in each image being obtained as the geometric center of the reflections in each cornea and the parallax of each eye between the two capture elements.

Abstract: In one embodiment, a method encodes a first set of segments of a media file based on a first bitrate range to generate a first set of encoded segments. It is then determined when an encoded segment for the first bitrate range includes a bitrate that satisfies a second bitrate range. When the encoded segment for the first bitrate range includes the bitrate that satisfies the second bitrate range, the method does not encode a segment in the first set of segments that corresponds to the encoded segment when the media file is encoded based on the second bitrate range to generate a second set of encoded segments for the second bitrate range. A first playlist for the first bitrate range is identified and a second playlist for the second bitrate range is identified. The second playlist also includes the encoded segment that was encoded for the first bitrate range.

Abstract: A mobile studio for producing video and audio content includes a vehicle having a body mounted on a chassis. The body includes a studio chamber enclosure formed by a floor, a ceiling, spaced opposite outer side walls and spaced outer front and rear walls, and the floor includes a stage area. The mobile studio further includes at least one LED lighting assembly located in the studio chamber enclosure that is suitable for providing sufficient illumination for image capture such that a captured image is suitable for projection as a Pepper's Ghost image, at least one camera to capture an image of a subject on the stage area and generate the captured image, and a communications device to transmit the captured image.

Abstract: A method of adjusting motion in a video sequence, includes performing motion estimation on an original video sequence and producing initial motion vectors and motion statistics, using the motion statistics to determine a level of motion estimation and motion compensation (MEMC) in the video sequence, adjusting a frame interpolation process based upon the level, and producing a frame interpolated video sequence from the original video sequence and the adjusted frame interpolation process.

Abstract: Provided are an around view monitoring (AVM) system and method for vehicles. A front camera of an AVM system for vehicles is replaced with a stereo camera of an AS system, and thus, a system is simplified. Also, the AVM system and the AS system use a camera in common, thereby reducing the cost.

Abstract: The present invention relates to a technique for encoding and decoding an image, and a method for encoding the image, according to the present invention, comprises the steps of: performing a prediction with respect to a current block; and transforming a residual which is generated by the prediction, wherein in the step of transforming, a first transform is performed on the residual, and then a second transform is performed on a lower frequency area, and wherein a mode of the second transform can be decided on the basis of a mode of the first transform.