Abstract: A method for processing a plurality of spectral datasets (J1-Jn) intended for being used by a molecular imaging method or a method for recording a plurality of spectral datasets (J1-Jn), each spectral dataset (J1-Jn) being defined by a set of spatial positions (Xi, Yj) each of which is associated with a molecular spectrum with at least two dimensions containing a set of molecular information (S(Xi, Yj)), the method including in particular the following steps: for each dataset (J1-Jn), cutting the molecular spectrum associated with each position (Xi, Yj) into a plurality of spectrum segments (T1-Tm); inserting the segments (T1-Tm) obtained for each position (Xi, Yj) of each dataset (J1-Jn) into a database (BDD); selecting in the database (BDD), following a request relating to molecular information of interest, the one or more segments (T1-Tm) containing the molecular information of interest; and selecting, within each segment (T1-Tm), the molecular information of interest.

Abstract: Systems and methods for authenticating a broadcast device using facial recognition are herein disclosed. The disclosure includes receiving, from a wearable device, a broadcast signal comprising an identification code of the wearable device; determining, using a processor, whether the identification code is stored within a database; identifying first facial data stored within the database, the first facial data associated with the identification code; generating second facial data; and determining, using the processor, whether the second facial data matches the first facial data. In an implementation, the broadcast device is a Bluetooth low energy device. In a further implementation, the broadcast device comprises the wearable device. In a still further implementation, the disclosure includes detecting gait data and determining whether the gait data matches gait feature data extracted from stored gait data features.

Abstract: A method for transmitting a computer display image. In one embodiment, the method comprises determining a pixel boundary, referenced to a sub-tile boundary within a grid of tiles, for a changed portion of the image; identifying i) a uniform tile within the changed portion referenced to a first tile and ii) at least one hybrid sub-tile, associated with the sub-tile boundary, within the changed portion referenced to a second tile adjacent the first tile; engaging an SIMD vector processor to transform the uniform tile to an exit matrix, transform the at least one hybrid sub-tile to at least one DC coefficient, and transform the exit matrix to a first DC coefficient and the at least one DC coefficient to a second DC coefficient; quantizing, encoding and transmitting coefficients of the first and second tiles; and transmitting a binary mask specification for the changed portion adjusted to the sub-tile boundary.

Abstract: The present invention provides a method and a device for processing an image of an upper garment, helpful to improve a user's experience during virtual fitting. The method for processing an image of an upper garment in the present invention comprises setting a collar image having an upper edge, a connecting line of two endpoints of which is in the horizontal direction, the distance between the two endpoints being equal to the distance between two end portions at a notch on a rear collar in a picture of upper garment without the rear collar, and the upper edge being in left-right axial symmetry and is convex or concave at a preset height or depth, overlaying the image of the upper garment without the rear collar on an upper layer of the neckline image, and superposing the two ends of the collar with the two endpoints of the upper edge.

Abstract: A representative value calculator calculates a representative value which is a luminance value representing a main inspection object area from an input image. On the other hand, an image divider divides an image area of the input image, and sets a plurality of divided ranges. A factor calculator calculates a tone conversion factor for enhancing or suppressing contrast adjacent the representative value calculated by the representative value calculator for each area (each divided area) divided by the image divider. A tone converter converts the tone of each pixel of the input image based on the tone conversion factor for the range divided by the image divider, which range includes a pixel for image processing, and ranges adjacent that range. As a result, the contrast of the area for which enhancement is desired can be enhanced optimally.

Abstract: A method for gait analysis of a subject performed periodically over time to detect changes in one or more gait characteristics. The method includes detecting and identifying a subject and analyzing the gait of the subject on a plurality of occasions. Analyzing the gait of the subject includes, a detecting body parts, generating a joint model depicting the location of the at least one joint in each of the at least two frames, using the joint model to segment a gait cycle for the at least one joint, and comparing the gait cycle to a threshold value to detect abnormal gait.

Abstract: In an ejection controller for an injection molding machine, an image of an ejection process for a molded article is captured, a point in time when the molded article starts to drop from a mold is obtained as a drop start time point, an ejection stop time point is set based on the obtained drop start time point, and an ejection operation of an ejection device is interrupted at the set time point. Thus, the ejection is interrupted in a predetermined position, so that an operator can manually remove the molded article.

Abstract: A method and an apparatus for generating an anti-forgery image are provided. The method includes: determining, according to a rule for setting bits, related parameters; determining a combination quantity of bits, according to the parameters; acquiring a width, height and code numeric value of the anti-forgery image to be generated and requesting a memory space for the anti-forgery image to be generated according to the width and height of the anti-forgery image to be generated; determining positions of the code points in the bits according to the parameters; determining the image cell's initial coordinate in the anti-forgery image to be generated according to a rule for setting coordinates; and drawing the image cell in the memory space according to the image cell's initial coordinate in the anti-forgery image to be generated, where the drawn image cell forms the anti-forgery image.

Abstract: In a method for optically capturing a fingerprint or an object on a surface (2) of a cover plate (1) of a screen with a plurality of photosensors (4) which are each assigned to a respective display pixel (6), the display pixels (6) emit light radiation and the photosensors (4) capture light radiation from the display pixels (6) reflected by the surface (2) within a scan angle (8). The scan angle (8) describes in a virtual mirror image plane (9) the size of the display pixel (6).

Abstract: A method of generating super resolution image data includes receiving original image data of a low resolution at an image processing device, performing motion compensation on the original image data using a current frame of image data and at least one previous frame of image data and at least one future frame of image data as reference frames, generating motion vectors, applying noise reduction to the current frame of image data and the reference frames to produce noise reduced, current frame image data, and generating a current frame of super resolution image data using the noise reduced, current frame image data.

Abstract: A system and method is provided which obtains different medical images (210) showing an anatomical structure of a patient and having been acquired by different medical imaging modalities and/or different medical imaging protocols. The system is configured for fitting a first deformable model to the anatomical structure in the first medical image (220A), fitting a second deformable model to the anatomical structure in the second medical image (220B), mutually aligning the first fitted model and the second fitted model (230), and subsequently fusing the first fitted model and the second fitted model to obtain a fused model (240) by augmenting the first fitted model with a part of the second fitted model which is missing in the first fitted model; or adjusting or replacing a part of the first fitted model based on a corresponding part of the second fitted model having obtained a better fit.

Abstract: An information processing apparatus for producing combined image data includes an image data acquiring unit that acquires two image data items a difference obtaining unit that obtains a difference in brightness between the data items a difference area identifying unit that identifies a difference area a surrounding brightness difference obtaining unit that obtains a difference between a brightness of the difference area and a brightness of an area located around the difference area a correction target area information producing unit that produces correction target area information which indicates a correction target area, in which one of the data items, having a greater difference obtained by the surrounding brightness difference obtaining unit, is used as the correction target area and a combined image data producing unit that produces the combined image data, based on the data items and the correction target area information.

Abstract: Disclosed is a method and system for processing images from an aerial imaging device. An image of an object of interest is received from the aerial imaging device. A parameter vector is extracted from the image. Image analysis is performed on the image to determine a height and a width of the object of interest. Idealized images of the object of interest are generated using the extracted parameter vector, the determined height, and the determined width of the object of interest. Each idealized image corresponds to a distinct filled volume of the object of interest. The received image of the object of interest is matched to each idealized image to determine a filled volume of the object of interest. Information corresponding to the determined filled volume of the object of interest is transmitted to a user device.

Abstract: A technique for 3D registration of three or more 3D models using parallel computing. The technique treats the pairwise 3D registration problem as an atomic sub-problem, and solves in parallel a plurality of pairwise 3D registration. The initial guess for the pairwise 3D registration is calculated based on the, possibly incomplete, information available at the moment the calculation is made. At each point the available pairwise transformations are examined based on current available information. Transformations that are identified as outliers or as inaccurate are marked for repeated pairwise 3D registration when additional information relevant for the calculation of the initial guess becomes available.

Abstract: A computer-implemented method for providing image quality optimization individualized for a user includes a computer receiving raw image data acquired from an image scanner and identifying one or more raw image quality features based on the raw image data. The computer automatically determines one or more target image quality features by applying one or more user preferences to the one or more raw image quality features. The computer also automatically determines one or more processing parameters based on the one or more target image quality features. The computer may then process the raw image data using the one or more processing parameters to yield an image.

Abstract: A method for preventing overlap during the application of a universal identifier (UID) to a signature document in an electronic signature service is disclosed. The method includes parsing an image file of the signature document to obtain a content vector. A set of addresses of the content vector uniquely correspond with a set of locations in the image. Each value in the content vector indicates content at a corresponding location in the image. The method also includes measuring an overlap quantity for a potential UID location using the content vector to measure the overlap quantity. The method also includes selecting a UID location in the signature document using the overlap quantity. The method also includes applying the UID to the signature document using the UID location.

Abstract: Method comprising, for each pixel, obtaining a pixel expansion exponent value (E?(p)) by low pass filtering luminance values of colors of pixels in its spatial neighborhood, obtaining a pixel luminance-enhancement value (Yenhance(p)) by extraction of high frequencies of luminance values of colors of pixels in its spatial neighborhood, and then inverse tone mapping the luminance (Y(p)) according to the equation Yexp(p)=Y(p)E?(p)×[Yenhance(p)]c.

Abstract: An underlay body includes a surface on which a writing medium is placed, and a sensor that detects a pressure distribution on the surface.

Abstract: When removing a block distortion occurring in a local decoded image, a loop filtering part 11 of an image coding device carries out a filtering process on each of signal components (a luminance signal component and color difference signal components) after setting the intensity of a filter for removing the block distortion for each of the signal components according to a coding mode (an intra coding mode or an inter coding mode) selected by a coding controlling part 1.

Abstract: The present disclosure provides a fingerprint identification device including a substrate, a contact layer, a processing unit, and a plurality of sensor electrodes. The substrate includes a first sub-substrate, a second sub-substrate, and an adhesive layer. The adhesive layer is between the first sub-substrate and the second sub-substrate. A plurality of first sub-holes is defined in the first sub-substrate. A plurality of second sub-holes is defined in the second sub-substrate. A plurality of third sub-holes is defined in the adhesive layer. One of the first sub-holes communicates a corresponding one of the third sub-holes and a corresponding one of the second sub-holes to define a corresponding hole. An end of each of the sensor electrodes is coupled to the processing unit. The other end of each of the sensor electrodes passes through one of the holes, extends to the contact layer, and is covered by the contact layer.