Abstract: A method for configuring a plurality of networked cameras includes sending a request to the plurality of networked cameras requesting information relating to enabled storage type of each networked camera, receiving a response from networked cameras. The response includes information relating to storage type enabled in networked camera. The method further includes determining storage type to use for each networked camera that are enabled to autonomously store images at a storage means, where the determining of storage type is performed based on the information relating to enabled storage types received from these networked cameras, and sending a storage instruction to each camera for which a storage type has been determined. The storage instruction instructs a camera to store captured images on a storage means of a specific type.

Abstract: In an in-vehicle camera 1, when an in-vehicle camera body 5 is hooked on a hook portion 33 of a bracket 3 attached to a windshield, a leaf spring 34 presses the in-vehicle camera body 5 against the bracket 3 to fix the in-vehicle camera body to the bracket 3. Therefore, the in-vehicle camera body 5 can be attached to the windshield without permitting the windshield to come off from the vehicle by the bracket's being strongly pushed such as by a jig, or without permitting the jig to scratch the windshield. Since the in-vehicle camera body is fixed to the bracket 3 by being pressed against the bracket 3 by the leaf spring 34, there is no problem of causing backlash relative to the bracket 3.

Abstract: When employing a multi-node computing architecture for commercial articulated vehicles to generate a composite surround view of the vehicle, each processing node is associated with a vehicle segment. Each node has its own processor, memory and sensors. A master-slave relationship exists in the architecture. The segment processors collect, format, manage and package their local information. Communication between nodes is controlled by the master node, which can limit, adjust, subsample and alter the information and information flow from the slave nodes. The slave nodes can be freely recombined, using a pre-established communication standard or a format agreed upon at combination time.

Abstract: The present invention provides measuring apparatus and method for three-dimensional profilometry of an object, wherein a random-speckle beam and a structured fringe beam are projected onto the object and reflected therefrom for forming deformed random-speckle beam and structured fringe beams that are separately acquired by an image acquiring device thereby obtaining a random-speckle image utilized to determine an absolute phase information of each position on the surface of the object, and a structured fringe image utilized to determine a relative phase information for each position of the surface of the object. Each absolute phase information and each relative phase information corresponding to each position are converted into an absolute depth and a relative depth, respectively. Finally, the depth information of each position on the surface of the object is calculated by combining the corresponding absolute depth and the relative depth whereby the surface profile of the object can be established.

Abstract: A dynamic image masking system for providing a filtered autonomous remote sensing image through a dynamic image masking process is provided. The dynamic image masking system has a remote sensing platform and an imaging system associated with the remote sensing platform. The imaging system has an optical system and an image sensing system. The dynamic image masking system further has a multi-level security system associated with the imaging system and one or more image alteration locations located in the imaging system and the multi-level security system, wherein alteration of one or more images takes place via the dynamic image masking process. The dynamic image masking system further has a computer system associated with the imaging system. The computer system has a gatekeeper algorithm configured to send gatekeeper commands to one or more controllers that control the one or more image alteration locations through the dynamic image masking process.

Abstract: A method and a measuring machine for determining dimensional properties of a measurement object each use a workpiece table and a camera having an image sensor and an imaging optics. The imaging optics exhibits aberrations and is configured to be focused on a plurality of different working positions relative to the workpiece table. The aberrations are minimized by using first calibration values provided for a defined working position. A first working distance of the camera relative to a region of interest is determined. Subsequently, the imaging optics is focused, using the first working distance and using second calibration values that represent an image field curvature of the camera, such that the region of interest is substantially brought into a defined working position. Subsequently, the image recording and image evaluation take place to determine measurement values that represent the dimensional properties of the measurement object in the region of interest.

Abstract: A method and apparatus provide the ability to code signals in a layered manner for compression and networking applications. The solution involves a relaxed hierarchical structure of layers, wherein only an optimal subset of information from lower quality levels is transmitted to higher level decoders. This framework is complemented with a design method to optimize system parameters. Specialization may include techniques for employing irregular quantizers and/or estimation theoretic optimal parameter selection and/or content specific optimization (e.g., exploiting harmonic structure in audio, adaptive transform coding and enhanced motion compensated prediction for video) and/or optimization of the structure of the layers, where the potential of exploiting all the common information is realized to improve overall system performance for that application. One specific technique provides improved compression of signals with multiple quality levels with or without prediction.

Abstract: The present invention relates to a people counter using a TOF camera and a method of counting people, and more particularly, to a people counter using a TOF camera that can easily check and count objects corresponding to people by filtering objects moving in an image on the basis of depth information obtained by the TOF camera, and a method of counting people. According to the present invention, it is possible to easily revise depth information and size information of an object, which are obtained by a TOF camera disposed on a ceiling, into actual depth and size information, and to ensure reliability in counting people without complicated setup and operation by providing the information so that an object corresponding to a person can be easily recognized and counted from image information obtained by filtering the information into depth information of a person.

Abstract: A video system includes at least one video subsystem including a video source coupled to a mobile platform. The video source is configured to capture and transmit video data. A video processing system is configured to receive transmission of the video data from the video subsystem at a plurality of locations in which the video subsystem is configured to transmit the video data to the video processing system automatically when the video subsystem is in range of the video processing system at each of the plurality of locations.

Abstract: Novel tools and techniques for monitoring railway track geometry. In one aspect, some such tools and techniques can determine a location of a platform along a railway, capture one or more images of the railway, and/or analyze the rail configuration at that point. In another aspect, some solutions might employ photogrammetric techniques to analyze the rail configuration and thereafter store data about the rail configuration, perhaps correlated with the location of the images, in a data store.

Abstract: A method for laser microdissection of a laser microdissection region of a prepared specimen includes driving a holder for the specimen into a holding position using a control device. First and second digital images are captured that depict a same portion of the prepared specimen, with the first image depicting the portion under at least one first microscopic examination method and the second image depicting the portion under at least a second microscopic examination method. A live overlay image is generated of the portion of the prepared image in a live mode. The live overlay is presented on a display area with the images overlaid onto one another. A marking is generated and captured on the live overlay image so as to define the laser microdissection region.

Abstract: An imaging device includes multiple sensor pixels that are arranged in a predetermined direction, each sensor pixel having multiple sensor pixel borders defining an outer edge part of the sensor pixel, among which at least one of a pair of sensor pixel borders that are opposed in the arrangement direction is oblique to a passage direction of a defect image that is vertical to the predetermined direction. This can provide an inspection tool enabling high sensitivity inspection and/or having improved detection reproducibility of a defect.

Abstract: In embodiments of imaging structure emitter configurations, an imaging structure includes a silicon backplane with a driver pad array. The embedded light sources are formed on the driver pad array in an emitter material layer, and the embedded light sources can be individually controlled at the driver pad array to generate and emit light. The embedded light sources are configured in multiple rows for scanning by an imaging unit to generate a scanned image for display.

Abstract: The present disclosure relates to deblocking filtering which is applicable to smoothing the block boundaries in an image or video coding and decoding. In particular, the deblocking filtering is either strong or weak, wherein the clipping is performed differently in the strong filtering and the weak filtering.

Abstract: In an inspection method, an inspection region of a sample is divided into a plurality of stripe regions, and is divided into a plurality of groups so that a plurality of continuously arranged stripe regions constitutes one group. An optical image of a graphic pattern arranged in a stripe region of one of the groups is acquired while moving a stage in a longitudinal direction of the stripe region. The stage is then moved in a lateral direction of the stripe region. An optical image of a graphic pattern arranged in a stripe region of a group different from one of the groups in which the optical image is acquired, and in a stripe region not continuous to the stripe region whose optical image is acquired immediately before the movement in the lateral direction, is acquired while moving the stage in the longitudinal direction of the stripe region.

Abstract: An endoscopic illumination system for illuminating a subject for stereoscopic image capture, includes a light source which outputs light; a first complementary multiband bandpass filter (CMBF) and a second CMBF, the first and second CMBFs being situated in first and second light paths, respectively, where the first CMBF and the second CMBF filter the light incident thereupon to output filtered light; and a camera which captures video images of the subject and generates corresponding video information, the camera receiving light reflected from the subject and passing through a pupil CMBF pair and a detection lens. The pupil CMBF includes a first pupil CMBF and a second pupil CMBF, the first pupil CMBF being identical to the first CMBF and the second pupil CMBF being identical to the second CMBF, and the detection lens includes one unpartitioned section that covers both the first pupil CMBF and the second pupil CMBF.

Abstract: Provided are a system and method for image sharpening is provided that involves capturing an image, and then decomposing the image into a plurality of image-representation components, such as RGB components for example. Each image-representation component is transformed to obtain an unsharpened multi-resolution representation for each image-representation component. A multi-resolution representation includes a plurality of transformation level representations. Sharpness information is transported from an unsharpened transformation level representation of a first one of the image-representation components to a transformation level representation of an unsharpened multi-resolution representation of a second one of the image-representation components to create a sharpened multi-resolution representation of the second one of the image-representation components. The sharpened multi-resolution representation of the second one of the image-representation components is then transformed to obtain a sharpened image.

Abstract: A reduced area imaging device is provided for use in medical or dental instruments such as an endoscope. The imaging device is provided in various configurations, and connections between the imaging device elements and a video display may be achieved by wired or wireless connections. A connector assembly located near the imaging device interconnects the imaging device to an image/power cable extending through the endoscope. The connector provides strain relief and stabilization for electrically interconnecting the imager to the cable. The connector also serves as the structure for anchoring the distal ends of steering wires extending through the body of the endoscopic device. The connector includes a strain relief member mounted over a body of the connector. The connector allows a steering wire capability without enlarging the profile of the distal tip of the endoscopic device.

Abstract: Apparatus and methods related to image taking and processing are provided. For example, some embodiments may contain a front facing camera and a back facing camera and can be used for including the image-taker as part of the images taken by the image-taker, for verifying authorship of the image, for creating documentary style still or moving images combining the images of the person creating the documentary and the images of the subject or the scene being documented, and for creating a wide field of views of still and moving images.

Abstract: Compressive sensing based video rate imaging techniques are presented. Rather than scan the entire image, the imaging system only scans part of the topography of the sample as a compressed scan. After the data has been collected, an algorithm for image reconstruction is applied for recovering the image. Because compressive sensing is used, the imaging rate is increased from several minutes per frame to seconds per frame. Non-vector space control techniques are also presented. No-vector space control use image or compressive data as the input and feedback to generate a closed-loop motion control. Compressive sensing technique provides an efficient data reduction method to retain the essential information in the original image. The non-vector space control method can be used as motion control method with compressive feedback without or with noise.