Abstract: A system encoding and decoding video that uses a parallel encoding and decoding technique.

Abstract: A masquerading detection system includes: an imaging unit (2) that obtains a first image by imaging an inspection object (12) from a first angle, and a second image by imaging the inspection object from a second angle which is different from the first angle; a unit (101) that detects first feature points from the first image, obtains first feature point coordinates of the detected feature points, detects second feature points from the second image, and obtains second feature point coordinates of the detected feature points; a unit (104) that obtains transformed coordinates by performing a plane projective transformation for the second feature point coordinates from the second image to the first image; and a unit (105) that determines that masquerading has been attempted when the difference between the transformed coordinates and the corresponding first feature point coordinates is equal to or smaller than a predetermined value.

Abstract: In a video decoding system, a method and system for decoding previously encoded frames of video into a compressed and uncompressed format. The uncompressed format frames may be further stored and utilized to decode additional frames of video. The compressed format frames may be further stored and provided to a display processor to be rendered with additional textures.

Abstract: A system encoding and decoding video that uses a parallel encoding and decoding technique.

Abstract: Systems and methods are provided for tracking at least position and angular orientation. The system comprises a computing device in communication with at least two cameras, wherein each of the cameras are able to capture images of one or more light sources attached to an object. A receiver is in communication with the computing device, wherein the receiver is able to receive at least angular orientation data associated with the object. The computing device determines the object's position by comparing images of the light sources and generates an output comprising the position and angular orientation of the object.

Abstract: A system encoding and decoding video that uses a parallel encoding and decoding technique.

Abstract: A charged particle beam device of the present invention has a signal processing function of acquiring a secondary signal obtained when a charged particle beam is caused to scan at a low speed not subjected to a band limitation of an electrical signal path, and a secondary signal obtained when a charged particle beam is caused to scan at a high speed subjected to the band limitation of the electrical signal path, calculating a degradation function (H?1(s)) between the plurality of secondary signals, and using an inverse function thereof as a correction filter; and a function of updating a parameter of the correction filter to an optimal value as needed or at given timing. Accordingly, the charged particle beam device can perform optimum image restoration even when a detector or an amplifier circuit that constitutes the electrical signal path degrades with time.

Abstract: A system encoding and decoding video that uses a parallel encoding and decoding technique.

Abstract: The invention relates to a method of iterative multi-layer decoding of a multimedia communication signal, wherein persistent bits from various upper layers of the employed protocol stack are used in error correction decoding at a lower error-correction layer. The method includes saving persistent bits from successfully decoded FEC frames in memory, and using a subset of the saved bits in decoding of future frames. A smart controller is used to analyze frames for the presence and location of persistent bits, for saving thereof in memory, and for inserting saved persistent bits into a next frame at successive decoding iterations thereof.

Abstract: An imaging apparatus includes first and second imaging units, a reading unit that reads pixel information from pixels set as a reading target in each of the first and second imaging units, a control unit that sets the pixels as the reading target in each of the first and second imaging units in a manner such that the pixel information is alternately read from the first and second imaging units by the reading unit, and controls timing of exposure processes in the first and second imaging units and timing of reading processes of the pixel information for the first and second imaging units by the reading unit, to be correlated with one another, a transmission unit that transmits the pixel information read from each of the first and second imaging units in a same transmission path, and an image processing unit that generates an image based on the pixel information.

Abstract: Techniques and tools for sub-block transform coding are described. For example, a video encoder adaptively switches between 8×8, 8×4, and 4×8 DCTs when encoding 8×8 prediction residual blocks; a corresponding video decoder switches between 8×8, 8×4, and 4×8 inverse DCTs during decoding. The video encoder may determine the transform sizes as well as switching levels (e.g., frame, macroblock, or block) in a closed loop evaluation of the different transform sizes and switching levels. The encoder and decoder may use different scan patterns for different transform sizes when scanning values from two-dimensional blocks into one-dimensional arrays, or vice versa. The encoder and decoder may use sub-block pattern codes to indicate the presence or absence of information for the sub-blocks of particular blocks.

Abstract: A system and method for calibrating a production film scanner is provided. The system and method provides for providing at least one first calibration frame on an intermediate film stock providing at least one second calibration frame on a negative film stock, scanning the at least first and second calibration frames with a reference film scanner, scanning the at least first and second calibration frames with a production film scanner, and determining a compensation calibration factor from a first result of the scanning with the reference film scanner and a second result of the production film scanner.

Abstract: A video multiviewer system may include a plurality of video inputs and a multiviewer video processor coupled to the plurality of video inputs for generating video data based upon the plurality of video inputs. The system may further include a display coupled to the multiviewer video processor for displaying multiple video windows based upon the video data, and at least one user input device. The multiviewer video processor may permit scrolling among the multiple video windows displayed on the display at a given instant and at least one other video window not displayed on the display at the given instant based upon the at least one user input device.

Abstract: This invention is directed to a transmission system having a broadcast data synchronization and transmission system including a stream unit which detects group of pictures (GOP) positions of a Motion Picture Expert Group (MPEG) stream to be broadcasted on a television, and a shot/scene unit which sets and marks Extendible Markup Language (XML) TAG information in the corresponding GOP positions detected by the stream unit.

Abstract: A video decoding method and apparatus and a video encoding method and apparatus based on a scanning order of hierarchical data units are provided. The decoding method includes: receiving and parsing a bitstream of an encoded video; extracting from the bitstream information about a size of a maximum coding unit for decoding a picture of the encoded video, and encoding information about a coded depth and an encoding mode for coding units of the picture, wherein the size of the maximum coding unit is a maximum size of a coding unit which is a data unit for decoding the picture; and determining a hierarchical structure of the maximum coding unit and the coding units into which the picture is divided according to depths, and decoding the picture based on the coding units, by using the information about the size of the maximum coding unit and the encoding information about the coded depth and the encoded mode.

Abstract: An endoscope includes: a CDS circuit that samples an image pickup signal from a CCD via a feedthrough sampling pulse SHP and a clamp pulse SHD to output a post-sampling image pickup signal; a CPU that controls a sampling timing of each of SHP and SHD and evaluates the post-sampling image pickup signal from the CDS circuit, and a flash memory that stores timing information on the respective timings and timing determination procedure information. The CPU, upon receipt of an adjustment instruction for adjustment of the respective timings of SHP and SHD, rewrites the timing information in the flash memory according to a result of evaluation of a plurality of post-sampling image pickup signals obtained by shifting the respective timings based on the timing determination procedure information.

Abstract: A decoder for decoding a plurality of digital video data is described. In an embodiment, the decoder comprises a DV video decoder for decoding digital video data which is formatted according to the DV standard. The DV video decoder has a Very-Long Instruction Word (VLIW) processor and a variable length decoding unit. The VLIW processor includes a preparser unit for recovering a decoding order of the digital video data so that the variable length decoding unit can process the digital video data. The variable length decoding unit decodes a variable length coding format of the digital video data which has been preparsed by the VLIW processor. Furthermore, the VLIW processor includes a decompression unit for decompressing the digital video data which has been decoded by the variable length decoding unit. In an embodiment, the VLIW processor and the variable length decoding unit are formed on the same semiconductor device.

Abstract: A portable remote control device enables user interaction with an appliance by detecting user gestures made in a hover zone, and converting the gestures to commands that are wirelessly transmitted to the appliance. The remote control device includes at least two cameras whose intersecting FOVs define a three-dimensional hover zone within which user interactions are imaged. Separately and collectively image data is analyzed to identify a relatively few user landmarks. Substantially unambiguous correspondence is established between the same landmark on each acquired image, and a three-dimensional reconstruction is made in a common coordinate system. Preferably cameras are modeled to have characteristics of pinhole cameras, enabling rectified epipolar geometric analysis to facilitate more rapid disambiguation among potential landmark points. As a result processing overhead and latency times are substantially reduced.

Abstract: An image processing device includes an image acquisition section that acquires an image that has been acquired by imaging a tissue using an endoscope apparatus, an in vivo position identification information acquisition section that acquires in vivo position identification information that specifies an in vivo position of the endoscope apparatus when the image has been acquired, a in vivo model acquisition section that acquires a in vivo model that is a model of the tissue, an on-model position determination section that specifies an on-model position that corresponds to the position specified by the in vivo position identification information on the acquired in vivo model, and a linking section that links information about the acquired image to the specified on-model position.

Abstract: According to one embodiment, a television receiver includes a display device, a first member, a second member, a support member, and a support portion. The display device includes a display screen and a side surface. The first member includes a first wall facing the side surface. The second member is located opposite the first member with respect to the display screen and includes a second wall facing the side surface. The support member is attached to the first member and located on the side surface of the first wall. The support member supports the display device on a side opposite the display screen. The support portion is provided to an end of the first member and includes a portion extending toward a side opposite the display screen on the side surface side of the second wall. The support portion supports the support member between the portion and the second wall.