Abstract: A further coding efficiency increase may be achieved if for a current block of a picture, for which the bit stream signals one of supported partitioning patterns, a reversal of the partitioning by block merging is avoided. In particular, if the signaled one of the supported partitioning patterns specifies a subdivision of the block into two or more further blocks, a removal of certain coding parameter candidates for all further blocks, except a first further block of the further blocks in a coding order, is performed. Particularly, those coding parameter candidates are removed from the set of coding parameter candidates for the respective further block, the coding parameters of which are the same as coding parameters associated with any of the further blocks which, when being merged with the respective further block, would result in one of the supported partitioning pattern. This avoids redundancy between partitioning coding and merging coding.

Abstract: A further coding efficiency increase may be achieved if for a current block of a picture, for which the bit stream signals one of supported partitioning patterns, a reversal of the partitioning by block merging is avoided. In particular, if the signaled one of the supported partitioning patterns specifies a subdivision of the block into two or more further blocks, a removal of certain coding parameter candidates for all further blocks, except a first further block of the further blocks in a coding order, is performed. Particularly, those coding parameter candidates are removed from the set of coding parameter candidates for the respective further block, the coding parameters of which are the same as coding parameters associated with any of the further blocks which, when being merged with the respective further block, would result in one of the supported partitioning pattern. This avoids redundancy between partitioning coding and merging coding.

Abstract: A system for scanning a body to create scan data comprises a processor, a range camera capable of capturing at least a first set of depth images of the body rotated to 0 degrees, and at least a second set of depth images of the body rotated to x degrees, wherein x is >0 degrees, and x <360 degrees. A set of computer instructions are executable on a processor capable of creating biometrics based on extracted body measurement from the body scan.

Abstract: In one embodiment of the present invention, an encode validator identifies and classifies errors introduced during the parallel chunk-based translation of a source to a corresponding aggregate encode. In operation, upon receiving a source for encoding, a frame difference generator creates a frame difference file for the source. A parallel encoder then distributes per-chunk encoding operations across machines and creates an aggregate encode. The encode validator decodes the aggregate encode and creates a corresponding frame difference file. Subsequently, the encode validator performs phase correlation operations between the two frame difference files to detect errors generated by encoding process faults (i.e., dropping a frame, etc.) while suppressing discrepancies inherent in encoding, such as those attributable to low bit-rate encoding.

Abstract: The general field of the invention is that of monochromatic stereoscopic image projectors including two light sources that illuminate two imagers, the radiation of the two light sources having a spectral distribution centred on a central wavelength, the first imager and the second imager being connected to a generator of stereoscopic image pairs. The image projector includes a dichroic separating filter that transmits the portion of the spectrum below the central wavelength and that reflects the portion of the spectrum above this central wavelength. The first light source and the second light source are arranged symmetrically on either side of the dichroic separating filter. The image projector operates cyclically, each cycle including two alternations. Each alternation consists in changing the emission source and in switching to the two displays the left and right images emitted by the generator of image pairs.

Abstract: Techniques for determining positions of devices within an environment are described herein. In some instances, an environment, such as a home or office of a user, may include an array of devices, some or all of which may couple to a network or to other devices via short-range wireless connections (e.g., Bluetooth®, Zigbee®, etc.). These devices may capture an array of data for providing to a central service, which is configured to analyze the data and, based on this analysis, determine a location of the devices relative to one another. That is, the central service may analyze the data to determine relative distances and orientations between the identified devices within the environment.

Abstract: A camera assembly arranged on an unmanned and autonomously navigating aerial vehicle is employed to inspect a surface area of for material defects. The vehicle is automatically flown to the surface area from a launch site, wherein it can fly around obstacles using automatic obstacle detection and avoidance methods. A relative position of the aerial vehicle with respect to the surface area with the aid of a position sensor is continuously measured and a sequence of images of the surface area is recorded. Between the individual images, the aerial vehicle is moved along a flight path overlapping image details of the surface area. The images of the sequence are composed into an overall image of the surface area to allow for the surface area to be inspected for defects and the location of defects to be ascertained on the basis of the overall image.

Abstract: It is provided a method for viewing an image that is wider or higher than the display screen, wherein, the image is evenly divided into two portions by using a line passing through centers of larger edges of the image compared to the display screen. The method comprises, at the side of shutter glasses, the steps of receiving a message indicating display of a first portion of the two portions; turning dark of the shutter glasses and turning refraction direction of the shutter glasses towards a first position; turning transparent of the shutter glasses; receiving a message indicating display of a second portion of the two portions; turning dark of the shutter glasses and turning refraction direction of the shutter glasses towards a second position; and turning transparent of the shutter glasses.

Abstract: An endoscope includes: pixels arranged in a matrix form and configured to generate an imaging signal according to an amount of received light, and output the imaging signal through one of vertical lines in the pixels, each two pixels adjacent to one another in a horizontal direction sharing a single vertical line; dummy pixels, each provided for each vertical line in the pixels; a determination unit for determining whether output values of dummy signals having been output multiple times from a dummy pixel of the dummy pixels, are within a range of a threshold; a correction data generator configured to: calculate, for each vertical line, a statistic of the output values of the dummy signals determined to be within the range of the threshold; and generate, for each vertical line, correction data based on the calculation; and a correction unit for correcting the imaging signal based on the correction data.

Abstract: An imaging control device according to an aspect of the present invention includes a rotation instruction input unit that receives an input of an instruction of rotation of a pan and tilt mechanism of a camera, a rotation instruction output unit that outputs the rotation instruction to the camera, an image input unit that receives a live view image according to the rotation instruction from the camera, and a display control unit that causes the display unit to perform a display for superimposing the live view image input from the camera on a limit display image of a two-dimensionally displayed spherical surface indicating an imagable region and a non-imagable region respectively corresponding to within a rotation limit and out of the rotation limit of the imaging unit of the camera, and rotating the limit display image along the two-dimensionally displayed spherical surface according to the input of the rotation instruction.

Abstract: A method and apparatus is disclosed for scanning a body. The system comprises a processor and a range camera capable of capturing at least a first set of depth images of the body rotated to 0 degrees and at least a second set of depth images of the body rotated to x degrees, wherein x is >0 degrees, and x<360 degrees. A first set of computer instructions executable on the processor is capable of calculating a first set of three dimensional points from the first set of depth images and a second set of three dimensional points from the second set of depth images. A second set of computer instructions executable on the processor is capable of rotating and translating the first and second set of three dimensional points into a final set of three dimensional points. A third set of computer instructions executable on the processor is capable of creating a three dimensional mesh from the final set of three dimensional points.

Abstract: A system for scanning a body to create scan data comprises a processor, a range camera capable of capturing at least a first set of depth images of the body rotated to 0 degrees, and at least a second set of depth images of the body rotated to x degrees, wherein x is >0 degrees, and x<360 degrees. a set of computer instructions are executable on a processor capable of synchronizing scan data and body measurements with a server.

Abstract: A processing-target image creating device creates a processing-target image based on a plurality of input images. The processing-target image creating device includes a coordinates-associating part configured to associate coordinates on each input image plane on which each input image is positioned, coordinates on a space model onto which each input image is projected, and coordinates on a processing-target image plane, and an image adjusting part configured to adjust the processing-target image by determining for each input image a re-projection angle of a re-projection line joining the coordinate and the coordinate. The image adjusting part determines for each input image slopes of the re-projection lines such that each coordinate on the processing-target image plane corresponding to an infinity line in each input image corresponds with each other on a dividing line between image parts corresponding to each input image on the processing-target image plane.

Abstract: The present invention relates to a method for encoding and decoding a video in a multi-layer structure supporting scalability and an apparatus therefor, and a method for decoding a video according to the present invention includes the steps of: deriving a prediction sample for the present block; restoring the present picture based on the prediction sample; applying the de-blocking filtering for the block edges in the restored present picture; and applying an offset for a sample of the restored picture.

Abstract: Methods and devices for reconstructing coefficient levels from a bitstream of encoded video data for a coefficient group in a transform unit. Greater-than-one flags are encoded by grouping them into tuples and by encoding a tuple-based value that is a function of the greater-than-one flags within that tuple. The tuple-based value may permit the decoder to infer the greater-than-one flags in some cases, in which case they are not encoded in the bitstream.

Abstract: A surveillance system is provided including an Internet-enabled (IP) camera and nodes that determine the location of a plurality of sensors, which are wirelessly connected to the IP camera. The nodes determine the position of the plurality of sensors and the IP camera through the use of position determining techniques including multilateration, trilateration, and triangulation. Additionally, line of sight positioning methods and global positioning system devices may be used in setting up a positional awareness system, which enables the IP camera to control systems based on condition information and positional awareness.

Abstract: A cell imaging apparatus captures images of cells contained in a liquid specimen comprising: an image capture unit including an objective lens, specimen cells each including an inner space which is capable of holding a liquid specimen and which is elongated in one direction, the specimen cells arranged such that the inner spaces are aligned in a row in a longitudinal direction of the inner spaces, a drive unit that moves at least one of: a) one or more specimen cells; and b) the objective lens; and a controller that controls the drive unit to move at least one of: a) one or more specimen cells; and b) the objective lens in the longitudinal direction and controls the image capture unit to capture images of cells contained in a liquid specimen held in the inner space of each of the specimen cells at multiple image capture positions.

Abstract: An imaging unit includes: an image sensor having an electrode pad and a light-receiving surface; a flexible printed circuit board having an inner lead connected to the electrode pad and extending from the image sensor in a direction opposite to where the light-receiving surface is provided; and one or more electronic components mounted on a first surface of the flexible printed circuit board, the first surface being on a side where the image sensor is provided. The flexible printed circuit board includes: an insulating base material; a first wiring layer on the base material on a side of the first surface; a first film for insulating the first wiring layer; a second wiring layer on the base material on a side of a second surface opposite to the first surface; and a second film for insulating the second wiring layer. The inner lead extends from the first wiring layer.

Abstract: A system and method for implementing a machine learning-based system for generating event intelligence from video image data that: collects input of the live video image data; detects coarse features within the live video image data; constructs a coarse feature mapping comprising a mapping of the one or more coarse features; receives input of the coarse feature mapping at each of a plurality of distinct sub-models; identify objects within the live video image data based on the coarse feature mapping; identify one or more activities associated with the objects within the live video image data; identify one or more interactions between at least two of the objects within the live video image data based at least on the one or more activities; composes natural language descriptions based on the one or more activities associated with the objects and the one or more interactions between the objects; and constructs an intelligence augmented live video image data.

Abstract: An image generation device includes an imaging unit 11, a projection unit 22, and a distance information generation unit 18, and a projection pattern includes unit patterns arranged in a plurality of rows in a first direction and in a plurality of columns in a second direction. A plurality of light dots include first dots and second dots which are light dots of different states from each other; the unit patterns arranged in the first direction have the light dot arrangements identical with each other; the unit patterns arranged in the second direction have light dot arrangements different from each other; the number of first dots among a plurality of light dots arranged in the first direction in each of the unit patterns is the same fixed number in each row in the second direction; and in a location other than the unit pattern, the number of first dots included in a row of the same length as the unit pattern in the second direction differs from the fixed number, in a certain row in the second direction.