Abstract: Present novel and non-trivial system, device, and method for generating a steering command for at least one forward-looking image capture device are disclosed. The steering command generating system is comprised of a source of navigation data, an avionics system processor (“ASP”) configured to receive the navigation data representative of a wind correction angle (“WCA”); generate steering data as a function of at least the navigation data and representative of a steering command commensurate to an angular difference; and provide the steering data to one or more forward-looking image capture device(s). In another embodiment, the ASP may further receive motion tracking data representative of a head position angular measurement and include the motion tracking data in the function for generating steering data. The angular difference may correspond to the WCA or the measurement of a head position angle.

Abstract: Some embodiments are directed to a radiation dosage monitoring system including a model generation module configured to generate a 3D surface model of a portion of a patient undergoing radiation treatment, an image detector configured to detect Cherenkov radiation and any subsequent secondary and scattered radiation originating due to the initial Cherenkov radiation emitted from the patient, a processing module configured to determine estimations of radiation applied to the patient utilizing the images from the image detector and the 3D model, and to utilize the determined estimations of radiation applied to the patient together with data indicative of the orientation of a radiation beam inducing emission of the Cherenkov radiation at a time when the radiation beam was applied to generate a 3D internal representation of the location of the portions of a irradiated patient resulting in the emission of the Cherenkov radiation.

Abstract: A method and apparatus for significance map coding for 4×4 TUs (transform units) and 8×8 TUs of video data are disclosed. The method comprises receiving at least one context selection table for a first TU associated with a first color component and generating a derived context selection table for a second TU associated with a second color component from said at least one context selection table. The first TU has a first size comprising of 4×4 and 8×8. The second TU has a second size comprising of 4×4 and 8×8. The second size is different from the first size, the second color component is different from the first color component, or both the second size is different from the first size and the second color component is different from the first color component. The derived context selection table is then used for significance map processing of the second TU.

Abstract: The three-dimensional measurement apparatus includes: a base camera for capturing a workpiece to acquire a first image; a reference camera for capturing the workpiece from a view point different from the base camera to acquire a second image; and a camera control unit for extracting multiple edge lines from the first and second images, calculating line-of-sight errors with respect to provisional three-dimensional coordinates, wherein the line-of-sight errors are calculated at an endpoint of a first edge line selected from the multiple edge lines of the first image and an endpoint of a second edge line extracted from the multiple edge lines of the second image to correspond to the first edge line, setting an evaluation function from the line-of-sight errors, and a three-dimensional constraint condition set based on a shape of the workpiece, and making an optimization calculation of the evaluation function to measure the three-dimensional coordinates of the workpiece.

Abstract: The present invention provides a system and method for adaptively compensating distortion caused by video compression, the method first conducts an edge texture detection and block boundary detection to an image, classifies the area where the pixels to be processed is located to determine whether the pixel is located at a ringing artifact prone area or near the block boundary with blocking artifact. Next, according to the area of the pixel to be processed and the degree of distortion, the present invention adaptively compensate the distortion using different filtering strategies, so as to improve image effect of low bit-rate transmission at the display end, so that a real time requirement that playing at a high-definition, and ultra high-definition display is satisfied.

Abstract: Techniques related to adaptive bitrate streaming for wireless video are discussed. Such techniques may include determining candidate bitrates for encoding segments of a source video. A minimum of the candidate bitrates may be selected and a segment of the source video may be encoded based on the selected encoding bitrate. The encoded bitstream may be transmitted wirelessly from a transmitting device to a receiving device, which may decode the bitstream and present the decoded video to a user.

Abstract: A system for encoding and/or decoding a video bitstream that includes a base bitstream and enhancement bitstreams representative of a video sequence. The receiver receives a video parameter set and a video parameter set extension, where the video parameter set extension includes decoder picture buffer parameters.

Abstract: A mobile terminal may include a camera module and a controller. The camera module may include a first capture unit to capture a subject to acquire a first image, a second capture unit to capture the subject to acquire a second image, an actuator disposed at least one of the first capture unit and the second capture unit, and a drive unit configured to drive the actuator. The controller may analyze a perceived 3-dimensional (3D) image formed by using the first image and the second image, and may produce a relative position compensation value corresponding to a relative displacement between the first capture unit and the second capture unit according to a result of the analysis. The drive unit may drive the actuator to control a relative position between the first capture unit and the second capture unit based on the relative position compensation value.

Abstract: An image processing system includes a processor and optical flow determination logic. The optical flow determination logic is to quantify relative motion of a feature present in a first frame of video and a second frame of video with respect to the two frames of video. The optical flow determination logic configures the processor to convert each of the frames of video into a hierarchical image pyramid. The image pyramid comprises a plurality of image levels. Image resolution is reduced at each higher one of the image levels. For each image level and for each pixel in the first frame, the processor is configured to establish an initial estimate of a location of the pixel in the second frame and to apply a plurality of sequential searches, starting from the initial estimate, that establish refined estimates of the location of the pixel in the second frame.

Abstract: A system for locating a cable tethered from a machine along a worksite is disclosed. The system includes a laser scanner and a color camera. A location unit generates a position of the machine. The system includes a processing device disposed on the machine and in communication with the laser scanner, the color camera and the location unit. The processing device determines a location of the cable based on signals from the laser scanner and the color camera. The system further includes a server remotely located with respect to the machine and disposed in communication with the processing device. The server is configured to record locations of the cable at different instances of time and generates a map of the cable based on the locations of the cable.

Abstract: This disclosure describes a bi-predictive merge mode in which a bi-predictive video block inherits motion information from two different neighboring blocks, wherein the two different neighboring blocks were each encoded in a uni-predictive mode. Bi-predictive coding may improve the ability to achieve compression in video coding. The described bi-predictive merge mode may increase the number of bi-predictive candidates that can be used in the context of merge mode coding by allowing two separate uni-predicted neighbors to be used to define bi-predictive motion information for a video block.

Abstract: A system is provided for determining a binary codeword for a symbol representing a transform coefficient within transform units (TUs) that divide up coding units (CUs) in a High Efficiency Video Coding (HEVC) system. The system determines a truncated rice prefix and, when a parameter variable is greater than zero, determines a truncated rice suffix for the symbol. The system determines a main prefix either from the truncated rice prefix alone, or from a combination of the truncated rice prefix and the truncated rice suffix. When the main prefix is the same as a comparison string, the system also determines a main suffix. The system determines the final binary codeword for the symbol either from the main prefix alone, or from a combination of the main prefix and the main suffix.

Abstract: An embedded light field display architecture to process and display three-dimensional light field data in a light field display is provided. The light field display architecture includes a plurality of hierarchical modules to decode compressed light field data associated with a light field and a plurality of tile modules embedded directly in the light field display to process light field data for display. A plurality of networking modules is also provided to transmit light field data among the hierarchical modules and the tile modules.

Abstract: This display includes a light source portion, a first heat radiation member for radiating heat generated by the light source portion, a rear housing covering the first heat radiation member in a state in contact with the first heat radiation member, and a cover member covering a rear surface of the rear housing so that the rear surface of the rear housing is partially exposed outward. The first heat radiation member is arranged on a region corresponding to a region of the rear housing exposed outward from the cover member as viewed from the side of the rear surface.

Abstract: There is provided an image pickup system for endoscope including: a light source; an image forming optical system; a focus lens driving section; an image pickup section outputting an image signal; an image signal amplifying section; an image brightness detecting section; a brightness adjusting section adjusting a brightness control condition such as a light quantity of the light source, an image pickup condition of the image pickup section and an amplification factor of the amplifying section so that brightness of an image becomes a predetermined brightness; an auxiliary AF section estimating a temporary focus position based on the brightness control condition; a control section setting a small scanning range including the temporary focus position; and a contrast AF section causing contrast AF to be performed in the scanning range.

Abstract: A method for panorama exposure correction can begin with the receiving of a hemispherical-coverage panoramic digital image set by a panoramic image stitching system. The hemispherical-coverage panoramic digital image set can be comprised of a ceiling image and at least three side images that are all captured simultaneously. The images of the image set can be aligned to create a panoramic image. Based on the alignment, overlapping regions between two adjacent side images and the ceiling image can be identified, the placement of blending seams can be determined, and the region of each image affected by a exposure correction can be determined. The exposure correction for each identified overlapping region can be determined. The exposure of the affected region of each image can then be adjusted in accordance with the determined exposure correction. A gradient blending can be performed for a predefined area across the blending seams.

Abstract: Apparatuses and methods are provided for determining whether a user intends to provide an input using an image of a control appearing on a surface. An apparatus may include first and second cameras to capture set and second sets of two or more images of the surface, and a unit to determine whether various conditions are true. A first condition is that a particular number of skin-color pixels are present within one cell of the two or more images. A cell location substantially coincides with the image of the control. A second condition is that the skin-color pixels persist for at least a particular time period. A third condition is that a region of skin-color pixels has a substantially rectangular shape. A fourth condition is that corresponding edges of skin-color pixels in the first and second sets of images are within a predefined offset distance. Additional conditions are disclosed.

Abstract: The invention relates to a device, comprising a camera unit, which is used to record images of the exterior area of a motor vehicle, and a cover element, which can be moved from a closed position to an open position by means of a drive, wherein the camera unit is behind the cover element and inaccessible from outside in the closed position of the cover element and images can be recorded in the open position of the cover element. For this purpose, the cover element has an outer surface facing away from the camera unit, and the drive interacts with a mechanism in such a way that the outer surface is always in the exterior area of the motor vehicle in each position of the cover element during the movement of the cover element between the closed position and the open position.

Abstract: A wireless transfer system includes: a wireless transmission section including: an input section configured to receive, as an input signal, one of a first video signal provided with ancillary information including identification information of a high-definition 3D/2D video signal and a second video signal not including the identification information; a video signal extraction section configured to extract one of the high-definition video signal and the second video signal from the input signal; an ancillary information extraction section configured to extract the ancillary information; a wireless video transmitter configured to wirelessly transmit extracted one of the high-definition video signal and the second video signal; and the like; and a wireless reception section including: a wireless video receiver configured to receive wirelessly transmitted one of the high-definition video signal and the second video signal; a wireless ancillary information receiver configured to receive the wirelessly transmitted

Abstract: A video decoding method includes extracting offset mergence information of a current largest coding unit (LCU), the offset mergence information indicating whether to adopt a second offset parameter as a first offset parameter of the current LCU; reconstructing the first offset parameter of the current LCU based on the offset mergence information, the first offset parameter including an offset type, an offset value, and an offset class of the current LCU; determining whether the current LCU is an edge type or a band type, based on the offset type; determining an edge direction according to the edge type or a band range according to the band type, based on the offset class; determining a difference value between reconstructed pixels and original pixels included in the offset class, based on the offset value; and adjusting pixel values of reconstructed pixels based on the difference value.