Abstract: Systems and methods for classifying defects detected on a wafer are provided. One method includes detecting defects on a wafer based on output generated for the wafer by an inspection system. The method also includes determining one or more attributes for at least one of the defects based on portions of a standard reference image corresponding to the at least one of the defects. The method further includes classifying the at least one of the defects based at least in part on the one or more determined attributes.

Abstract: A generation circuit generates first palette information from a decoded image of a first block used for predicting second palette information of a second block in a coding target image when the first block has not received palette coding. A storage circuit stores the first palette information. A coding circuit performs prediction coding on the second palette information by using the first palette information so as to generate coded palette information.

Abstract: A page orientation component of an image processing device receives an image of a document, transforms the image to a binarized image by performing a binarization operation on the image, and identifies a portion of the binarized image that comprises one or more rows of textual content. The page orientation component identifies a plurality of horizontal runs of white pixels and a plurality of vertical runs of white pixels in the one or more rows of textual content in the portion of the binarized image. The page orientation component generates a first histogram for the plurality of horizontal runs of white pixels, and a second histogram for the plurality of vertical runs of white pixels, and determines an orientation of the one or more rows of textual content in the image based on the first histogram and the second histogram.

Abstract: An image processing system acquires a digital image and determines notional weights for each pixel in the image. The notional weight of each pixel relates to the pixel's color value of the pixel and may include adjustments. The system uses the notional weights for each pixel to determine a center of balance (CoB) for the image. The system may then determine an eccentricity of the CoB based on a distance between the CoB and a specified location in the digital image. The system may calculate an aesthetic score for the digital image as a function of the determined eccentricity. The system may display an augmented reality overlay on the image to show the CoB and/or other determined features. The system may use the CoB, eccentricity or aesthetic value to help improve a real-time image capture process, in a security protocol, and/or to determine whether to retain an image in memory.

Abstract: Methods, systems, and apparatus, including medium-encoded computer program products, facilitate determining information about an object included in an image. In one aspect, a method includes: identifying an image; identifying a specific object included in the image; identifying data associated with the image; determining both a dimension of the specific object and a construction material of the specific object using the identified data; and outputting the dimension and the construction material of the specific object.

Abstract: The capture and alignment of multiple 3D scenes is disclosed. Three dimensional capture device data from different locations is received thereby allowing for different perspectives of 3D scenes. An algorithm uses the data to determine potential alignments between different 3D scenes via coordinate transformations. Potential alignments are evaluated for quality and subsequently aligned subject to the existence of sufficiently high relative or absolute quality. A global alignment of all or most of the input 3D scenes into a single coordinate frame may be achieved. The presentation of areas around a particular hole or holes takes place thereby allowing the user to capture the requisite 3D scene containing areas within the hole or holes as well as part of the surrounding area using, for example, the 3D capture device. The new 3D captured scene is aligned with existing 3D scenes and/or 3D composite scenes.

Abstract: An automated signaling equipment inspection system is provided. The system includes signaling equipment, a LiDAR imaging device permanently installed close to the signaling equipment at a position and with an orientation allowing complete imaging of the orientation and configuration in space of the signaling equipment and of any potential movement of the signaling equipment during its operation, an image data processing device for detecting a non-conformity of the signaling equipment, and a reference image database storing reference image data of the signaling equipment. The LiDAR imaging device is configured to scan the signaling equipment to obtain real image data thereof. The image data processing device is configured to detect a non-conformity of the signaling equipment by comparing the real image data with reference image data taken from the reference image database.

Abstract: An image processing apparatus includes a first obtaining unit that obtains an image pickup condition of a shot image, a second obtaining unit that obtains information on an optical transfer function based on the image pickup condition, and a processor that generates an image restoration filter using the information on the optical transfer function and performs image processing on the shot image using the image restoration filter. The processor performs the image processing on the basis of information on noise characteristics of the image pickup condition.

Abstract: A ridge flow based fingerprint image quality determination can be achieved independent of image resolution, can be processed in real-time and includes segmentation, such as fingertip segmentation, therefore providing image quality assessment for individual fingertips within a four finger flat, dual thumb, or whole hand image. A fingerprint quality module receives from one or more scan devices ridge-flow-containing imagery which can then be assessed for one or more of quality, handedness, historical information analysis and the assignment of bounding boxes.

Abstract: Apparatus and methods for disparity cost computation for a stereoscopic image. In an example, a method includes computing partial path matching costs for multiple disparities of pixels of multiple parallelogram blocks of an image in a forward pass direction. Between computing the partial path matching costs of the pixels of adjacent parallelogram blocks, the method includes computing partial path matching costs for the plurality of disparities of pixels along a boundary edge of a corresponding rectangular tile using paths that are external to the rectangular tile and computing partial path matching costs the disparities for all of the pixels of the corresponding rectangular tile. The method also includes computing total aggregated disparity costs for each disparity of the pixels of the image using the partial path matching costs computed for the pixels in the parallelogram blocks and in the rectangular tiles.

Abstract: A method for inspecting an object to assist in determining whether the object has a surface defect. The method includes moving the object in a first direction and illuminating the object under ambient lighting conditions. The method also includes capturing at least one image of the object under the ambient lighting conditions while the object moves in the first direction. In addition, the object is illuminated under object lighting conditions and at least one image of the object under the object lighting conditions is captured while the object moves in the first direction to provide at least one object image. Further, the method includes selecting at least one object image having at least one indication of a possible defect to provide images having defect candidates and comparing the defect candidates with previously defined characteristics associated with the defect to facilitate determination of whether a defect exists.

Abstract: The invention generally relates to devices and systems for individually barcoding sample vessels. In certain embodiments, the devices comprise an attachment member and an extension member, where the extension member can accommodate an identifier, such as a barcode. When loaded into a substrate, the barcoded vials are scanned by a barcode reader.

Abstract: A detected quadrilateral area is displayed and no group of candidate lines is displayed in a normal state. While a user is selecting a side that the user desires to change, a group of candidate lines corresponding to the selected side is displayed. Then, whether to replace a position of the selected side with a position of a candidate line is determined based on a movement destination position of the selected side.

Abstract: A prelam layer for use in forming a laminated card includes a flexible circuit substrate; a fingerprint sensor disposed on the flexible circuit substrate, the fingerprint sensor having upper and bottom surfaces, the bottom surface of the fingerprint sensor being disposed on the substrate, an active layer of the fingerprint sensor disposed towards the upper surface of the fingerprint sensor; a first integrated circuit chip disposed on the substrate and having at least one lead electrically connected to the flexible circuit substrate; and an adapter flexible circuit electrically bonded to the active layer of the fingerprint sensor. The integrated circuit chip is adapted to communicate with the fingerprint sensor through the adapter flexible circuit.

Abstract: Embodiments of the present disclosure relate to systems, techniques, methods, and computer-readable mediums for one or more database systems configured to perform image identification of an image captured using a remote mobile device, and display of identity information associated with the captured image on the remote mobile device, in communication with the database system(s). A system obtains an image captured using a camera on a remote mobile device and performs image analysis to identify the captured image using reference images in one or more databases. The system can present the results for display an interactive user interface on the remote mobile device.

Abstract: A method for mapping a geographical location of a feature in a satellite image is provided. An image of a geographical surface is obtained, the image comprising a plurality of pixels, data indicating the latitude and longitude of each vertex of the image and data relating to a grid corresponding to the image is obtained. A grid location of a feature in the image is received, the grid location identifying a cell in the grid. The grid location is translated into a geographical location, which comprises calculating a pixel space location of at least one vertex of the identified grid cell; converting the pixel space into a latitude/longitude space based on the obtained data indicating the latitude and longitude of each vertex; and determining the latitude and longitude of the at least one vertex of the identified cell, based on the calculated pixel space location and the latitude/longitude space.

Abstract: The disclosure features methods and systems that include a detector configured to obtain multiple images of a sample stained with first and second stains, where the first and second stains have similar spectral absorption and emission profiles, and an electronic processor configured to decompose the multiple images into an unmixed image set, where the unmixed image set includes a first unmixed image corresponding to the first stain and a second unmixed image corresponding to the second stain, and identify nuclear regions in the sample based on the first unmixed image and identify cytoplasm regions in the sample based on the second unmixed image.

Abstract: Embodiments of the present invention provide systems, methods, and computer storage media directed towards automatic selection of regions for blur kernel estimation. In one embodiment, a process divides a blurred image into a regions. From these regions a first region and a second region can be selected based on a number of edge orientations within the selected regions. A first blur kernel can then be estimated based on the first region and a second blur kernel can be estimated for the second region. The first and second blur kernel can then be utilized to respectively deblur a first and second portion of the image to produce a deblurred image. Other embodiments may be described and/or claimed.

Abstract: A method of characterizing fragmentation of an explosive device (110) comprises receiving a image of a witness plate (100) that has been subject to impact by fragments from explosion of the device; warping the image to remove deformations of the plate (100); marking strike damage sites (120) caused by impact of the fragments; and recording the position and area of the strike damage sites (120).

Abstract: The current invention concerns a method for detecting cancerous cells and/or classifying cells in a cell sample comprising the following steps: providing a cell sample; obtaining holographic information from said cell sample by digital holographic microscopy (DHM); deriving at least one cellular parameter from said holographic information, and; classifying said cells of cells sample; characterized in that said classification occurs by appointing a Scoring Factor to said cells of cell sample, based on said cellular parameters. In a second aspect, a system for the detection of cancerous cells and/or classification of cells in a cell sample is provided, employing the method as disclosed in the invention. In a final aspect, a method for updating and/or improving a database comprising thresholds linked to holographic information and the database related thereof is equally disclosed.