Abstract: A method for encoding video and an encoder for encoding video, a method for decoding video and a decoder for decoding video are provided. Accordingly, in one embodiment, a method for decoding video receives a bit-stream including a plurality of data units encoded according to a scan pattern comprising at least one U-pattern, and decodes a data unit among the plurality of data units by using at least one data unit included among the plurality of data units, the at least one other data unit being decoded prior to the data unit according to the scan pattern. When the plurality of data units are included in a data cluster, the method includes scanning the plurality of data units according to the at least one U-pattern, and the scanning includes scanning and decoding the data unit, followed by scanning and decoding a neighboring data unit horizontally or vertically adjacent to the data unit.

Abstract: Disclosed are methods and systems such as an imaging assembly that may include a variety of components, such as, but not limited to, a two-dimensional (2D) camera configured to capture 2D image data, a three-dimensional camera configured to capture three-dimensional (3D) image data, and an evaluation module executing on one or more processors. The 2D camera may be oriented in a direction to capture 2D image data of a first field of view of a container loading area, and the 3D camera may be oriented in a direction to capture 3D image data of a second field of view of the container loading area at least partially overlapping with the first field of view. The evaluation module may be configured to detect a status event in the container loading area based on 2D image data.

Abstract: An image processing method and apparatus for performing sample adaptive offset (SAO) processing are provided. The image processing method includes: performing, based on a largest coding unit (LCU) and a coding unit (CU), an encoding operation on a frame image; setting a maximum offset having a value adjusted according to a maximum transformation size in the encoding operation; and calculating, based on the set maximum offset, a sample adaptive offset (SAO) parameter for use in SAO compensation.

Abstract: A vehicular vision system includes an electronic control unit having at least four coaxial connectors. At least four coaxial cables are electrically connected at respective coaxial connectors of the electronic control unit and respective cameras of at least four cameras. Each of the coaxial cables carries DC power from the electronic control unit to the respective camera. Each of the coaxial cables carries image data captured by an imager of the respective camera to the electronic control unit. Image data carried to the electronic control unit is processed at the electronic control unit by a processor of the electronic control unit. Each of the coaxial cables provides monodirectional data transfer of captured image data from the respective camera to the electronic control unit. Each of the coaxial cables provides bidirectional data transfer of other data between the respective camera and the electronic control unit.

Abstract: Embodiments include a spectral reflectance system comprising a detector and a light source coupled to a support member. The system includes a turret coupled to the support member. The turret is configured to receive objective lenses and configured to selectively position each lens in an imaging position relative to a sample to be imaged. A first objective lens is configured to image the sample at the detector when placed in the imaging position. A second objective lens includes an optical director that is configured to form an optical path with an auxiliary detector and image the sample at the auxiliary detector when the second objective lens is in the imaging position.

Abstract: An example device for decoding encoded video data includes storage media and processing circuitry. The storage media are configured a portion of the encoded video data. The processing circuitry is configured to determine a block-level threshold for the portion of the encoded video data stored to the storage media, to determine that an encoded block of the portion of the encoded video data has a size that is equal to or greater than the threshold, to receive a syntax element indicating that a portion of the encoded block is to be reconstructed using a coding tool, to determine, based on the encoded block having the size that is equal to or greater than the threshold, that the syntax element applies to all samples of a plurality of samples included in the encoded block, and to reconstruct the encoded block based on the coding tool.

Abstract: Provided is an image processing apparatus including an information acquisition section that acquires setting information to set a motion vector to a second prediction unit in a second layer corresponding to a first prediction unit in a first layer of a scalable-video-decoded image containing the first layer and the second layer, which is higher than the first layer, the setting information being related to a motion vector set to the first prediction unit, and a motion vector setting section that sets the motion vector to the second prediction unit using the setting information acquired by the information acquisition section.

Abstract: Among other things, an imaging device has a photosensitive array of pixels, and a surface associated with the array is configured to receive a specimen with at least a part of the specimen at a distance from the surface equivalent to less than about half of an average width of the pixels.

Abstract: A communication assembly may include a first antenna. The communication assembly may further include a housing that houses the first antenna and an electronics enclosure. The housing may include a bottom that may be disposed on a fuselage of a vehicle. The electronics enclosure may include a radio frequency module and a camera module. The electronics enclosure may transmit heat to the fuselage of the vehicle by the bottom of the housing.

Abstract: A video encoding method for encoding both the 4:2:0 video and 4:4:4 video formats. The method includes generating blocks of quantized spatial frequency data by quantizing coefficients and generating a matrix of data. The method further includes determining quantization matrices for use with at least two block sizes. The method further includes determining a first quantization matrix for a 32×32 chroma block of samples with respect to a first modification of a first scaling list for quantization of a block of samples smaller than 32×32, and determining, for blocks of another block size different than the 32×32 chroma block of samples, a second quantization matrix by modifying a second scaling list according to a second modification. The second scaling list is different from the first scaling list, and the first scaling list is a reference scaling list for video in 4:2:0 video format.

Abstract: A camera monitor system includes: left and right capturing devices; left and right displaying devices; and a control device detecting an abnormality of each of the left and right capturing devices and controlling a displaying state of each of the left and right displaying devices based on the detected abnormality. The control device individually controls each of the left and right displaying devices to be in a low power consumption state in accordance with a mode of the detected abnormality.

Abstract: A signaling of the layer ID is described with which each of the packets of a multi-layered video signal is associated. In particular, an efficient way of signaling this layer association is achieved, while maintaining the backward compatibility with codecs according to which a certain value of the base layer-ID field is restricted to be non-extendable. Instead of circumventing this restriction specifically with respect to this non-extendable base layer-ID value, the layer-ID of portions of the multi-layer data stream is signaled in an extendable manner by sub-dividing the base layer-ID field into a first sub-field and a second sub-field: whenever the first sub-field of the base layer-ID field fulfills a predetermined criterion, an extension layer-ID field is provided, and if the first sub-field of the base layer-ID field does not fulfill the predetermined criterion, the extension layer-ID field is omitted.

Abstract: A method, system, and computer program product for compressing an image using similar images includes: receiving a first image; storing the first image on a storage server; comparing the first image to one or more stored intra-frames (I-Frames) to determine a similar I-Frame from the one or more stored I-Frames; in response to determining the similar I-Frame, determining that one or more stored predicted frames (P-Frames) reference the similar I-Frame; comparing the first image to the one or more stored P-Frames to determine a similar P-Frame; determining whether the first image meets a P-Frame threshold level for the similar P-Frame; in response to determining that the first image meets the P-Frame threshold level, generating a first P-Frame for the first image using data from the similar P-Frame and data from the similar I-Frame to compress storage space used by the first image on the storage server.

Abstract: An athletic training system (200) has a data recording system (202) and a data engine (204). The data recording system (202) is configured to record an athletic competition event. The event may have a first team of players competing against a second team of players. The data engine (204) is configured to receive data associated with the recorded athletic competition event. The data engine (204) processes the data and displays the data as a replay of the event in animated form.

Abstract: A display device includes a display member configured to display an image in a first direction and a cover member on the display member. The cover member includes a flexible member including a front part defining a front plane perpendicular to the first direction, and a first side part connected to a first side of the front part and defining a first side plane different from the front plane, and a rigid member partially overlapping the flexible member and on the front part.

Abstract: A multi-optic vision device includes a dark-vision lighting apparatus illuminating a defect on a subject and leaving regions that surround the defect dark. A bright-vision lighting apparatus illuminates the subject and the regions that surround the defect and leaving the defect dark. A differential-vision lighting apparatus illuminates the subject so as to stereoscopically show the defect on the subject. An area scan camera continuously imaging the subject as the dark-vision lighting apparatus, the bright-vision lighting apparatus, and the differential-vision lighting apparatus simultaneously and respectively provide light. A controller processes the image to respectively obtain a dark-vision image, a bright-vision image, and a differential-vision image of the subject.

Abstract: The disclosed technology is directed to a floating system capable of facilitating transmitting underwater signals (e.g., images captured underwater) to an abovewater device. The system includes a first housing, a second housing, an antenna, a signal emitter, a signal converter, and a signal interface. The first and second housings collectively form an enclosed space. The antenna is vertically positioned on the top surface of the first main body. The signal emitter and the signal converter are positioned in the enclosed space and coupled to the antenna. The signal interface is positioned on the bottom surface of the second housing and coupled to the converter. A user can connect an underwater camera to the signal interface and transmit images captured underwater to another abovewater device through the floating system.

Abstract: Systems and methods are provided for logging tests of electronic devices, which are performed on the electronic devices by a measurement and/or testing device. While logging the test messaged and any other messages generated by the measurement and/or testing device during the test, a video is recorded of the respective electronic device and timely synchronized with the log of the test.

Abstract: A method and system for allocating a variable number of bits per frame in a distributed video encoding using a complexity analyzer is disclosed. The method includes receiving an input video for allocating the number of bits for each segment based on the complexity of the segment. Further, the method includes splitting the input video into plurality of segments. Further, the method includes determining the number of bits to be allocated to the plurality of segments based on the complexity measurement of the input video. In an embodiment, single complexity analyzer can be used to determine the complexity of the plurality of segments. In another embodiment, separate complexity analyzer can be used for each segment to determine the complexity. Further, the method includes allocating the bits to the plurality of segments of the input video. Further, the method includes combining the plurality of segments to form a single output video; thereby, obtaining the encoded output video.

Abstract: A method including receiving first camera information that is indicative of visual information from a first camera location, causing display of the first camera information, receiving second camera information that is indicative of visual information from a second camera location, identifying an object that is represented in the first camera information and represented in the second camera information, receiving an object selection input that designates a representation of the object from the first camera information, receiving an object movement input that is indicative of movement in relation to the object, determining that a direction of the object movement input is opposite to a direction from the first camera location to the second camera location, and causing transition from display of the first camera information to display of the second camera information is disclosed.