Abstract: This invention provides a single-camera vision system, typically for use in logistics applications, that allows for adjustment of the camera viewing angle to accommodate a wide range of object heights and associated widths moving relative to an imaged scene with constant magnification. The camera assembly employs an image sensor that is more particularly suited to such applications, with an aspect (height-to-width) ratio of approximately 1:4 to 1:8. The camera assembly includes a distance sensor to determine the distance to the top of each object. The camera assembly employs a zoom lens that can change at relatively high speed (e.g. <10 ms) to allow adjustment of the viewing angle from object to object as each one passes under the camera's field of view (FOV). Optics that allow the image to be resolved on the image sensor within the desired range of viewing angles are provided in the camera lens assembly.

Abstract: Provided is a technique for enhancing the display quality of a stereoscopic image. A display apparatus includes a parallax barrier, a detector, a predictor, and a controller. The detector detects a position of an observer. The predictor predicts, on the basis of a plurality of positions detected by the detector at past times, the position of the observer at a time coming after the past times, at which the plurality of positions have been detected. The controller determines a parallax barrier pattern selectively switching a plurality of barriers to a light transmissive state, and controls the parallax barrier on the basis of the parallax barrier pattern.

Abstract: The motion of objects within a scene may be detected and tracked using digital (e.g., visual and depth) cameras aligned with fields of view that overlap at least in part. Objects may be identified within visual images captured from the scene using a tracking algorithm and correlated to point clouds or other depth models generated based on depth images captured from the scene. Once visual aspects (e.g., colors or other features) of objects are correlated to the point clouds, shapes and/or positions of the objects may be determined and used to further train the tracking algorithms to recognize the objects in subsequently captured frames. Moreover, a Kalman filter or other motion modeling technique may be used to enhance the prediction of a location of an object within subsequently captured frames.

Abstract: Aspects of the subject disclosure may include, for example, selecting a set of traffic counters, wherein the traffic counters provide a profile of viewing habits of a user, and wherein the traffic counters are extracted from video streaming by the user; predicting a size of a video buffer based on the traffic counters selected; and building the video buffer based on the predicted size. Other embodiments are disclosed.

Abstract: Techniques include constraining depth intra mode coding in a three-dimensional (3D) video coding process, such as 3D-High Efficiency Video Coding (3D-HEVC). In some examples, the techniques for constraining depth intra mode coding may prevent transform tree nodes from being split into sub-transform tree nodes when a depth prediction unit that corresponds to the transform tree node is predicted according to a depth modeling mode (DMM). In further examples, the techniques for constraining depth intra mode coding may prevent the DMM mode from being used when the maximum transform unit size that corresponds to a depth prediction unit is greater than the size of the depth prediction unit. The techniques for constraining depth intra mode coding may prevent characteristics of the DMM prediction modes used in 3D-HEVC and characteristics of the transform tree subdivision used in 3D-HEVC from interfering with each other.

Abstract: Digitization of film, and more particularly film scanning, includes capturing light transmitted through the film so as to acquire a digitized image. This includes a captured frame comprising a digitized image of at least a portion of at least one image frame of a sequence of image frames, and at least a portion of one or more transport perforations. The method can further include determining an image offset corresponding to at least the captured frame on the basis of a comparison between at least one detected edge in the captured image and a corresponding datum location. A signal representing the image offset can be generated to enable alignment of at least the captured frame.

Abstract: Disclosed herein are techniques for camera illuminator control. These techniques can be used in cameras that include an RGBIR (red green blue infrared) camera sensor and two illuminators—one visible light illuminator and one infrared illuminator. The techniques provide timing and control for such cameras for a variety of different camera modes. Particular camera modes may be defined as having different camera mode values for different camera mode parameters. That is, any particular camera mode is defined by a particular camera mode value for each of a set of camera mode parameters. Different parameters include a flash periodicity parameter, a simultaneity parameter, an autoexposure mode parameter, a shutter mode parameter, and a frame drop parameter.

Abstract: The present invention is directed to providing an around view monitoring system (AVMS) that may enhance accuracy of an estimation of a camera attitude while a road gradient is present, and an operating method thereof. According to an embodiment of the present invention, the AVMS may calculate a rotation matrix for removing a road gradient component using a camera that has not changed position and generate an estimated rotation matrix from which the road gradient is removed by applying the rotation matrix to an estimated rotation matrix for a camera that has changed position.

Abstract: A virtual viewpoint image generation system generates a virtual viewpoint image based on a plurality of captured images obtained by capturing an image capturing target region from a plurality of different directions, and position information relating to a virtual viewpoint position. The system comprises: a plurality of image capturing apparatuses; a daisy-chain-type topology network; an obtainment unit configured to obtain the position information relating to the virtual viewpoint position; and a generation unit configured to generate the virtual viewpoint image based on the position information and the data based on each captured image of the plurality of image capturing apparatuses obtained via the daisy-chain-type topology network.

Abstract: A sub-block entropy coding method more efficiently encodes content. Specifically, by selecting the most optimal tables for each sub-block, the number of bits utilizes is minimized. Furthermore, based on results, tables are able to be eliminated as options to further reduce the number of signaling bits.

Abstract: Disclosed herein are a camera module for a vehicle and a monitoring system provided with the same capable of conveniently identifying circumstances around a vehicle by photographing the circumference of the vehicle in various directions. According to an exemplary embodiment of the present invention, the camera module includes a camera module including a plurality of lenses which is mounted in different directions to form each image, one image sensor unit which is mounted to be movable to corresponding positions of each image formed by the plurality of lenses, a guide part which selectively moves the image sensor unit, and an image processor which processes an image signal output from the image sensor unit.

Abstract: An exemplary embodiment provides an image processing apparatus. The image processing apparatus includes a first object control unit for changing an orientation or a direction of movement of a first object in a three-dimensional space, a virtual camera control unit for determining a direction of shooting of the virtual camera in the three-dimensional space, and a display data generation unit for generating display data based on the determined direction of shooting of the virtual camera. The virtual camera control unit includes a detection unit for detecting whether the first object is hidden by another object when viewed from the virtual camera and a first following change unit for increasing a degree of causing the direction of shooting of the virtual camera to follow the orientation or the direction of movement of the first object based on a result of detection.

Abstract: Approaches to produce verification are addressed which may be suitably employed in conjunction with a low resolution image scanner. Features, such as lines, corners, text, texture, edges and the like are extracted and compared with features for an identified item or evaluated to determine if the features collectively are indicative of a produce item or a non-produce item.

Abstract: The image decoding method includes: determining a context for use in a current block to be processed, from among a plurality of contexts; and performing arithmetic decoding on a bit sequence corresponding to the current block, using the determined context, wherein in the determining: the context is determined under a condition that control parameters of neighboring blocks of the current block are used, when the signal type is a first type, the neighboring blocks being a left block and an upper block of the current block; and the context is determined under a condition that the control parameter of the upper block is not used, when the signal type is a second type, and the second type is “intra_chroma_pred_mode”.

Abstract: Various embodiments concern video patient monitoring with detection zones. Various embodiments can comprise a camera, a user interface, and a computing system. The computing system can be configured to perform various steps based on reception of a frame from the camera, including: calculate a background luminance of the frame; monitor for a luminance change of a zone as compared to one or more previous frames, the luminance change indicative of patient motion in the zone; and compare the background luminance to an aggregate background luminance, the aggregate background luminance based on the plurality of frames. If the background luminance changed by more than a predetermined amount, then the aggregate background luminance can be set to the background luminance, luminance information of the previous frames can be disregarded, and motion detection can be disregarded.

Abstract: In an example, a method of coding video data includes obtaining one or more video coding layer (VCL) network abstraction layer (NAL) units of an access unit and a first layer of a multi-layer bitstream of video data. The method also includes only coding one or more non-VCL NAL units containing an SEI message applicable to the VCL NAL units of the first layer together with the VCL NAL units of the first layer such that within the access unit the bitstream does not contain any coded pictures of any other layer of the multi-layer bitstream between the VCL NAL units of the first layer and the non-VCL NAL units containing the SEI message applicable to the VCL NAL units of the first layer.

Abstract: An apparatus and method for screen content encoding includes deriving a palette table and a color index map based on a coding unit (CU). The method also includes encoding the palette table and encoding the color index map. The method further includes combining the encoded palette table and the encoded color index map for transmission to a receiver, where the palette table and index map are decoded to reconstruct a pixel block.

Abstract: [Object] To provide a medical observation apparatus and a medical observation system that can ensure the user's visual field and have good manipulability.

Abstract: A side rearview vision assembly for a vehicle includes a base that is fixedly secured to the vehicle. A support arm is pivotally secured to the base. A positioning arm is secured to the support arm and is movable with respect to the support arm. The positioning arm defines a distal end. A camera is attached to the distal end of the positioning arm such that the camera moves with the positioning arm as the positioning arm moves relative to said support arm. The camera is configured to provide images exterior to the vehicle. A camera motor is operatively connected to the camera and changes its orientation with respect to the distal end of said positioning arm.

Abstract: A virtual viewpoint image generation system generates a virtual viewpoint image based on a plurality of captured images obtained by capturing an image capturing target region from a plurality of different directions, and position information relating to a virtual viewpoint position. The system comprises: a plurality of image capturing apparatuses; a daisy-chain-type topology network; an obtainment unit configured to obtain the position information relating to the virtual viewpoint position; and a generation unit configured to generate the virtual viewpoint image based on the position information and the data based on each captured image of the plurality of image capturing apparatuses obtained via the daisy-chain-type topology network.