Abstract: One exemplary embodiment involves receiving a plurality of three-dimensional (3D) track points for a plurality of frames of a video, wherein the 3D track points are extracted from a plurality of two-dimensional source points. The embodiment further involves rendering the 3D track points across a plurality of frames of the video on a two-dimensional (2D) display. Additionally, the embodiment involves coloring each of the 3D track points wherein the color of each 3D track point visually distinguishes the 3D track point from a plurality of surrounding 3D track points, and wherein the color of each 3D track point is consistent across the frames of the video. The embodiment also involves sizing each of the 3D track points based on a distance between a camera that captured the video and a location of the 2D source points referenced by the respective one of the 3D track points.

Abstract: Systems, devices, and methods are described for identifying, classifying, differentiating, etc., objects. For example a hyperspectral imaging system can include a dark-field module operably coupled to at least one of an optical assembly, a dark-field illuminator, and a hyperspectral imaging module. The dark-field module can include circuitry having one or more sensors operable to acquire one or more dark-field micrographs associated with scattered electromagnetic energy from an object interrogated by the dark-field interrogation stimulus. The hyperspectral imaging module can be operably coupled to the dark-field module, and can include circuitry configured to generate an angular-resolved and spectrally resolved scattering matrix based on the one or more dark-field micrographs of the object.

Abstract: A method, apparatus, article of manufacture, and a memory structure for signaling the storage of motion information describing the depicted motion associated with digital pictures. In one embodiment, the method comprises signaling the replacement of a motion vector stored in connection with a previously coded picture with the motion vector of the currently coded frame. Another signal may be used to indicate motion vector replacement for all pictures in a sequence.

Abstract: An image display apparatus according to an embodiment of the present invention comprises: an IR emitter controller for recognizing a pair of 3D glasses connected to the image display apparatus; a video multiplexer for receiving a plurality of displayed video data using a plurality of pairs of 3D glasses, setting a frame rate for the plurality of video data to assign a frame period thereto, and multiplexing the plurality video data according to the frame period assigned at the set frame rate, when the plurality of pairs of 3D glasses is connected to the image data apparatus; and a display unit for frame-sequentially displaying the multiplexed video data.

Abstract: Methods for removing redundancies in a video stream based on efficient pre-transmission detection of static portions of the video stream. In one embodiment supporting wireless transmission of a video stream having a series of video frames, a mathematical operation (such as a hash function, summing operation or CRC) is performed on (1) a (reconstructed) data block(s) of a video frame in order to generate a first check value and (2) a co-located data block(s) of a second, sequential video frame in order to generate a second check value. The first and second check values are compared to detect static video content in the video stream. When static video content in a video stream is detected, the static nature of the content is indicated in the compressed bit stream and the amount of wirelessly transmitted data corresponding to the static portions of the video stream may be reduced.

Abstract: Provided is a method that constructs an MPM group including three intra prediction modes, determines the intra prediction mode of the MPM group specified by the prediction mode index as the intra prediction mode of the current prediction unit if the mode group indicator indicates the MPM group, and derives the intra prediction mode of the current prediction unit using the prediction mode index and the three prediction modes of the MPM group if the mode group indicator does not indicate the MPM group. Accordingly, additional bits resulted from increase of a number of intra prediction mode are effectively reduced. Also, an image compression ratio can be improved by generating a prediction block similar to an original block.

Abstract: An extended depth of field microscope system for phase object detection includes an imaging optical module and a phase/intensity converting module. The imaging optical module has an object lens group, in which an axial symmetric phase coding is added, to produce an axial symmetric spherical aberration. A point spread function (PSF) and an image with extended depth of field can be obtained with a predetermined level of similarity. The phase/intensity converting module converts the phase change of the light passing the phase object, into an image light with change of light intensity.

Abstract: A catadioptric optical system includes a first imaging optical system including a catadioptric part configured to condense a light flux from an object and to form an intermediate image of the object, and a second imaging optical system including a dioptric part configured to form an image of the intermediate image on an image surface. The light flux from the object passes through the light transmission part of the first optical element, the negative lens, the backside reflection part of the second optical element, the negative lens, the backside reflection part of the first optical element, the negative lens, and the light transmission part of the second optical element, in this order, and is emitted to the second imaging optical system. An Abbe number of a material of the negative lens is larger than that of a material of the second optical element.

Abstract: In general, techniques are described for transforming video data in accordance with a three dimensional (3D) input format. As one example, an apparatus, such as a mobile or portable device, that includes a transformation module, a parameter discovery module and at least one interface implements the techniques. The parameter discovery module determines an input format supported by a 3D display device. The parameter discover module then configures the transformation module to transform two-dimensional (2D) video data into 3D video data so as to generate the 3D video data in accordance with the determined input format. The at least one interface receives 2D video data. The transformation module transforms the 2D video data to 3D video data so that the 3D video data complies with the determined input format. In this manner, the apparatus implements the techniques to transform video data in accordance with a determined 3D input format.

Abstract: An enclosure for enclosing a flat panel display. A bezel includes a peripheral surface defining an enclosure area and an inner edge defining a display opening. A substantially transparent front cover operatively connects to the bezel and covers the display opening. An enclosure housing includes a front opening and an access opening substantially opposite the front opening. An access opening cover is configured to cover the access opening. A sealing member receiving region is defined by one of the enclosure housing and the access opening cover, and a sealing member is operatively connected to the sealing member receiving region. When the access opening cover is operatively connected to the enclosure housing, an interface between the enclosure housing and the access opening cover is substantially sealed and is resistant to liquid ingress.

Abstract: A two dimensional/three dimensional (2D/3D) switchable display module, comprising a display panel, an optical module and a revising circuit is disclosed. The display panel has an active area. The optical module is disposed on the active area for changing a light path of a light emitting from the active area. A relative position information is between a position of the optical module and a position of the display panel. The revising circuit is used for providing a revising information based on the relative position information. The display panel receives the revising information and outputs an image corresponding to the optical module for displaying a three dimensional image.

Abstract: Methods of encoding a live video signal in a video encoding system including a plurality of video capture and encoding subsystems include providing the live video signal and an associated time code signal to the plurality of video capture and encoding subsystems, starting video capture and encoding in a first one of the subsystems at a first frame of the live video signal, starting video capture and encoding in a second one of the subsystems at a second frame of the live video signal that is later than the first frame, generating encode frame timestamps for the second frame in both the first and second video capture and encoding subsystems that are synchronized across the first and second subsystems, and associating the encode frame timestamp with the second frame in both the first and second subsystems. Related systems are also disclosed.

Abstract: An apparatus, system, and method utilizing multi-description coding (MDC) for multimedia content with a plurality of forms of diversity. A source scene can be fragmented into one or more region of interest (ROI) portions and non-ROI portions, based on motion or any other metric of interest. One or more of these portions can further be fragmented by sub-sampling the respective portions to generate a plurality of lower-resolution versions, e.g., with alternating groups of pixels in respective versions. Still further, one or more of these portions can be further fragmented by image frames, e.g., with alternating frames in respective fragments. At least one ROI portion and lower-resolution versions may then be encoded into a plurality of descriptions and transmitted. Utilizing various combinations of ROI diversity, resolution diversity, and frame rate diversity can improve channel utilization and robustness for streaming multimedia content.

Abstract: An apparatus to monitor one or more utility meters includes a communication unit with a processor, a communication interface coupled to the processor, and a probe interface coupled to the processor. A meter monitoring probe that includes a probe head is coupled by a cable to a probe connector capable to mate with the probe interface. The probe head includes an image sensor, an indicator, and a button. The probe head is capable to detect a characteristic of a utility meter that is dependent on a usage of a utility metered, and send information related to the characteristic to the processor. The processor is capable to receive the information from the probe head and send a message related to the usage of the utility over the communication interface, and the image sensor is capable to capture an image in response to a press of the button.

Abstract: In video/image coding, macroblocks (MBs) are often intra coded in raster scan order, starting from one seed MB. The invention improves intra prediction for optimized usage of multi-core processors. Encoding starts from multiple intra coded seed MBs per frame, and continues with adjacent MBs. A predefined prediction spread pattern (growth pattern) is used that comprises simultaneous prediction of two or more adjacent MBs per MB. Adjacent MBs with high coding cost are called “Hold-MB” and can be held from being processed, until another neighboring edge is available for prediction. Encoding comprises marking a MB with high coding cost for deferred prediction. This MB is skipped while the other MBs are encoded. When a further adjacent MB was encoded, the marked MB is predicted based on the adjacent MBs. Since a decoder receives the deferment marks and uses the same growth pattern, it follows the encoder, and predicts and decodes correctly.

Abstract: A variety of implementations are described. At least one implementation modifies one or more images from a stereo-image pair in order to produce a new image pair that has a different disparity map. The new disparity map satisfies a quality condition that the disparity of the original image pair did not. In one particular implementation, a first image and a second image that form a stereo image pair are accessed. A disparity map is generated for a set of features from the first image that are matched to features in the second image. The set of features is less than all features in the first image. A quality measure is determined based on disparity values in the disparity map. The first image is modified, in response to the determined quality measure, such that disparity for the set of features in the first image is also modified.

Abstract: Technologies are generally described herein for extracting a representative motion flow from a video. Technologies are also generally described herein for retrieving a video utilizing the representative motion flow. The representative motion flow may be extracted utilizing a sliding window approach to generate interesting motion flows. The representative motion flow may be generated based on the interesting motion flows.

Abstract: A digital camera includes a first optical system including a first optical axis; a second optical system including a second optical axis which is different from the first optical axis; a first image sensor and a second image sensor for detecting subject images; and a controller for performing focus control on each optical system and for instructing each image sensor to execute shooting operation. The controller instructs the first image sensor and the second image sensor to execute shooting operation at a first timing when the focus operation for the first optical system is finished or a second timing when the focus operation for the second optical system is finished, which is later.

Abstract: A stereoscopic image display device comprises a display panel which is controlled so that image frame data are stored for frame intervals and are displayed for blank intervals, each of the blank interval being between the frame intervals; a polarization control panel which positioned on the display panel and converts a polarization state of light passing through the display panel; and polarization glasses which creates stereoscopic images by restricting the light converted by the polarization control panel and reaching each eye.

Abstract: What is disclosed is a novel video processing system and method wherein a plurality of image frames of a video captured using a video camera with a spatial resolution of (M×N) in the (x, y) direction, respectively, and a temporal resolution (T) in frames per unit of time. A first and second magnification factor f1, f2 are selected for spatial enhancement in the (x, y) direction. A third magnification factor f3 is selected for a desired temporal enhancement in (T). The video data is processed using a dictionary comprising high and low resolution patch cubes which are used to induce spatial and temporal components in the video where no data exists. A high resolution course video X0 is generated which has an enhanced spatial resolution of (f1*M)×(f2*N) and an enhanced temporal resolution of (f3*T) frames. The course high resolution video is then smoothed, when found required, to generate a smoothed high resolution video.