Abstract: An information handling system comprising a storage device for receiving a first infrared image and a second infrared image of a temperature observation area captured from a first infrared camera, each infrared image having a segmented field of view, wherein the segmented field of view of the first infrared image overlaps at least in part the segmented field of view of the second infrared image and wherein the network adapter receives temperature recording data from a first remote point source temperature probe located within at least one of the segmented fields of view and processor is operatively coupled to the memory and network adapter and executes code instructions of an image-stitching module for calibrating the first infrared image based on temperature values from the temperature recording data received from the first remote point source temperature probe and stitches the first infrared image together with the second infrared image to create a first combined infrared image by detecting one or more shar

Abstract: A pattern inspection apparatus includes a first half-wave plate to receive an ultraviolet light linearly polarized in a first electric field oscillation direction, and output a linearly polarized light polarized in a second electric field oscillation direction obtained by rotating by an integer multiple of 90°, a mirror to reflect the linearly polarized light polarized in the second electric field oscillation direction, and output a linearly polarized light polarized in a third electric field oscillation direction parallel or orthogonal to the second electric field oscillation direction, a second half-wave plate to convert the linearly polarized light polarized in the third electric field oscillation direction, which has been reflected, to a linearly polarized light polarized in a fourth electric field oscillation direction by rotating by an angle different from an integer multiple of 90°.

Abstract: Provided are a geo-location or navigation camera, and an aircraft and a navigation method therefor. The geo-location or navigation camera comprises an image capturing apparatus (15), an image capturing direction of the image capturing apparatus (15) being vertically downward. The camera further comprises a gimbal stability-enhancement system comprising a gimbal body and a gimbal control system connected to the gimbal body. The image capturing apparatus (15) is arranged on the gimbal body. By means of the balance control and shock absorption effects of the gimbal stability-enhancement system, the stability of the image capturing apparatus (15) is better, and the image capturing direction of the image capturing apparatus (15) is maintained to be always vertically downward. The aircraft can still be navigated without a GPS. The method has advantages of being highly accurate and widely applicable.

Abstract: An image frame interpolation apparatus includes a motion vector generator configured to generate a motion vector based on a first image frame and a second image frame; a motion scaler configured to scale the motion vector to thereby generate a scaled motion vector; and a motion compensator including an internal memory, the motion compensator being configured to perform motion compensation based on the scaled motion vector and generate an interpolation frame using the internal memory, the motion scaler being configured to scale the motion vector based on a size of the motion vector and a size of the internal memory.

Abstract: An information processing apparatus acquires an image obtained by photographing a part of the subject, specifies a relative position which part of the subject is photographed to obtain the image, determines a specific area included in the obtained image based on the specified relative position, and calculates an edge amount of the specific area. Then, in a case where the calculated edge amount in the specific area is larger than a first threshold, a character recognition processing is performed on the specific area included in the acquired image.

Abstract: Method, apparatus and computer readable media for receiving a multiprogram program transport service that includes one or more compressed video services and one or more 3D-2D conversion options, generating an uncompressed video signal by performing a decoding portion of a transcoding operation for one of the one or more of the video services, determining from the 3D-2D conversion option whether a 3D-2D conversion is to be performed, performing a scale conversion on the uncompressed video according to a specified type of 3D-2D conversion, generating a compressed video service by performing an encoding portion of a transcoding operation on the uncompressed video that has been scale converted, and generating a second multiprogram program transport service that includes the compressed video signal that has been 3D-2D converted.

Abstract: A method and system are presented in which images are captured from overview and detail imaging devices such that overview images are created with a first degree of redundancy, and detail images are captured with less overlap and a second degree of redundancy.

Abstract: A system comprising a plurality of camera sensors and a processor. The camera sensors may each be configured to generate a video signal having a view. The processor may be configured to (a) generate an output video signal by selecting one or more of the video signals and (b) present the selected output video signal to a display for viewing. The output video signal may be automatically selected in response to a selection signal. The selection signal may be generated in response to analysis of one or more images in the video signals. The analysis of the one or more images in the video signals may comprise determining an appropriate view for a driver. The processor may remove possible warping present in the video signals.

Abstract: Embodiments relate to a method and a system for performing image compression and decompression of image data. In one or more embodiments, the image data is divided into one or more image data blocks, and the image compression and decompression are performed for each image data block. The image data block is compressed and includes a base value corresponding to a first image component and a compressed difference value corresponding to a second image component. For decompression, a first value of the image data block can be obtained based on the base value, and a second value of the image data block can be obtained based on the first value, the first compressed difference value and a corresponding quantization table. An output image can be presented to a user, according to the decompressed image data block.

Abstract: Apparatuses and methods configured to encode and decode multi-layer video are provided. A method of prediction-decoding a multi-layer video includes obtaining information indicating whether a decoded picture buffer (DPB) storing a first layer and a DPB storing a second layer operate identically, and operating the DPB storing the second layer based on the obtained information.

Abstract: A vehicle image capture and labeling system operates to enable a user to capture vehicle photos, pictures, and/or images that are automatically labeled, i.e., annotated. In particular, the captured vehicle photos, pictures, or images are automatically labeled with certain vehicle identifier information, like a vehicle identification number (VIN), and pose information, that identifies a portion or view of the vehicle depicted within the image of the vehicle. The vehicle images may also be automatically labeled with one or more other image attributes or indicia, such as geospatial information corresponding to a location at which the photo or image was captured (e.g., global positioning system (GPS) data), time and date of image capture data, etc. The captured vehicle image and its label(s) may then be stored and used by other applications such as vehicle insurance claim applications, automobile repair estimate applications, etc.

Abstract: Described is a multiple-camera system for use in capturing images of users within a materials handling facility and processing those images to monitor the movement of users. For large materials handling facilities, a large number of cameras may be required to monitor the facility. Processing of the data generated from a large number of cameras becomes difficult. The implementations described herein include a hierarchy that allows image data from any number of cameras within a materials handling facility to be processed without substantially increasing the processing time needed or sacrificing processing capabilities.

Abstract: There is provided a medical camera head including: a first casing configured to accommodate an imaging element; a heat-generating section accommodated in the first casing; a connection section provided in the first casing, an external signal transmission section being connected to one end of the connection section; and a heat transfer member interposed between the heat-generating section and the other end of the connection section.

Abstract: A vehicle-mounted camera has a lens disposed on a protruding part, which protrudes from the upper surface of a vehicle-mounted camera body; thus, compared to the situation in which the entire vehicle-mounted camera body is positioned below a bracket, the lens can be positioned at the shortest distance from a windshield, thereby enabling the length of a hood to be reduced. Furthermore, the in-vehicle camera is able to take up a large area of the portion of the bracket affixed to the windshield.

Abstract: The invention relates to a light microscope comprising a polychromatic light source for emitting illumination light in the direction of a sample, focussing means for focussing illumination light onto the sample, wherein the focussing means, for generating a depth resolution, have a longitudinal chromatic aberration, and a detection device, which comprises a two-dimensional array of detector elements, for detecting sample light coming from the sample. According to the invention, the light microscope is characterized in that, for detecting both confocal portions and non-confocal portions of the sample light, a beam path from the sample to the detection device is free of elements for completely masking out non-confocal portions. In addition, the invention relates to a method for image recording using a light microscope.

Abstract: Image scanning systems which scan images of objects as they are transported along a conveying system and methods of such scanning are provided. The optical system includes a conveying system, and optical elements positioned at least one of above, below and to a side of the conveying system such that a scan line is tilted with respect to an imaging surface of the conveyed object.

Abstract: There is provided a medical camera head including: a first casing configured to accommodate an imaging element; a heat-generating section accommodated in the first casing; a connection section provided in the first casing, an external signal transmission section being connected to one end of the connection section; and a heat transfer member interposed between the heat-generating section and the other end of the connection section.

Abstract: Summarization segments of an encoded video can be efficiently identified, without the need to decode the encoded video to obtain image data, by analyzing encoded-buffer-size deltas, each indicating an encoded-buffer-size difference between a pair of intra-coded frames of an encoded video.

Abstract: An imaging device includes an angular velocity sensor for detecting an angular velocity of shake and a motion vector detection unit for detecting a motion vector of an object from a plurality of images successively imaged by an imaging element. A frame rate change unit changes a value of a frame rate related to an image used to detect the motion vector of the object according to the angular velocity of shake of the imaging device. The object angular velocity calculation unit calculates an angular velocity of an object with respect to the imaging device based on the angular velocity of shake of the imaging device and the motion vector of the object. A panning controller performs control to reduce a difference between the angular velocity of the object and the angular velocity of shake of the imaging device using drive control of a shift lens group.

Abstract: Embodiments of the present invention provide techniques for coding video data efficiently based on detection of objects within video sequences. A video coder may perform object detection on the frame and when an object is detected, develop statistics of an area of the frame in which the object is located. The video coder may compare pixels adjacent to the object location to the object's statistics and may define an object region to include pixel blocks corresponding to the object's location and pixel blocks corresponding to adjacent pixels having similar statistics as the detected object. The coder may code the video frame according to a block-based compression algorithm wherein pixel blocks of the object region are coded according to coding parameters generating relatively high quality coding and pixel blocks outside the object region are coded according to coding parameters generating relatively lower quality coding.