Abstract: Methods and systems detect markings or flaws on the backs of playing cards. The method includes: providing ambient radiation at a gaming table and reflecting some of that radiation off a back surface of a playing card; capturing reflected radiation with a radiation sensor; the radiation sensor transmitting signals based on the reflected radiation captured by the radiation sensor; the transmitted signals providing data that contains image data of the back of the playing card; and displaying an image of the back of the playing card based on the image data. The transmitted signals provide image data of the back of the playing card and are also received by a processor that evaluates or compares that data. The system may be an installed casino system (with eye-in-the-sky technology), a portable box, or a component within a shuffling device or dealer shoe.

Abstract: A suitability detector identifies a plurality of frames of an input video. The suitability detector determines, based on characteristics of the plurality of frames, whether the input video is suitable for conversion from monoscopic visual content to stereoscopic 3D. The characteristics may include a visual cue present in the plurality of frames and a visual quality of the plurality of frames. If the input video is suitable for conversion, an image converter converts the input video to stereoscopic 3D.

Abstract: A moving-body-detecting device is provided with an image capture unit, an image conversion unit, a three-dimensional-object-detecting unit, a turn detecting unit, and a control unit. The image capture unit captures images of the rear side of a vehicle. The image conversion unit performs viewpoint conversion of the captured images into bird's-eye view images. The three-dimensional-object-detecting unit generates differential waveform information based on a differential image of bird's-eye view images taken as different points in time, and detects three-dimensional objects based on the differential waveform information. The control unit suppresses detection of the three-dimensional object based on the differential waveform information, in cases in which turning of the vehicle has been detected as compared with cases in which the vehicle is not turning.

Abstract: A cable safety and maintenance vision system includes an imaging unit comprising at least one imaging device configured to capture images of a side profile portion of a cable. The cable forms a continuous cable loop. A cable defect detection processor is in communication with the at least one imaging device. The cable defect detection processor is configured to receive images from the at least one imaging device, to identify features in the images that indicate potential defects, and to output a location on the continuous cable loop of the features in the images that indicate potential defects.

Abstract: The present invention relates to an encoding device, an encoding method, a decoding device, and a decoding method capable of encoding and decoding multi-viewpoint images in accordance with a mode that is compatible with an existing mode. A compatible encoder generates a compatible stream by encoding an image A1 that is a compatible image in units of access units. An auxiliary encoder generates an encoded stream of a multiplexed image of auxiliary images by encoding a multiplexed image of images B1 and C1 that are auxiliary images used when multi-viewpoint images are generated from the compatible image in units of access units. A multiplexing unit transmits the compatible stream, a 3DV Representation Delimiter representing a boundary of a unit, and an encoded stream of the multiplexed image of the auxiliary images. The present technology can be applied to, for example, an encoding device that encodes a 3D image of the multi-viewpoint mode.

Abstract: The invention provides a video codec. In one embodiment, the video codec is coupled to an outer memory storing a reference frame, and comprises an interface circuit, an in-chip memory, a motion estimation circuit, and a controller. The interface circuit obtains in-chip data from the reference frame stored in the outer memory. The in-chip memory stores the in-chip data. The motion estimation circuit retrieves search window data from the in-chip data with a search window, and performs a motion estimation process on a current macroblock according to the search-window data. The controller shifts the location of the search window when the current macroblock is shifted, marks a macroblock shifted out from the search window as an empty macroblock, and controls the interface circuit to obtain an updated macroblock for replacing the empty macroblock in the in-chip memory from the reference frame stored in the outer memory.

Abstract: An image capturing apparatus comprises an object detection unit configured to detect a predetermined object and a movement amount acquisition unit configured to acquire an amount of movement of the predetermined object. An object tracking unit suppresses the amount of movement of the predetermined object by moving an optical element constituting an image capturing optical system. A motion vector detection unit detects a motion vector indicating an image blur amount. An image blur correction unit corrects image blur based on the motion vector. A switching unit switches whether or not to perform object tracking using the object tracking unit. The image blur correction unit makes effect of the image blur correction in a case of performing the object tracking smaller than effect of the image blur correction in a case of not performing the object tracking.

Abstract: An apparatus for viewing images of a gemstone is described. The apparatus comprises a support structure for supporting the gemstone at an observation position. An illumination structure comprises a plurality of directional light sources directed towards the observation position so as to illuminate the gemstone. The support structure and illumination structure are relatively rotatable relative to one another about a rotation axis. An imaging device is arranged to obtain images of the gemstone at the observation position at a variety of relative rotational positions between the illumination structure and support structure: the imaging device has an imaging axis passing through the observation position. The support structure is arranged so that the gemstone can be placed at the observation position in such a way that the normal to a selected facet of the gemstone is within a range of tilt angles from the rotation axis.

Abstract: Vision-assist systems including user eye tracking cameras are disclosed. A vision-assist system includes a processor, a memory module communicatively coupled to the processor, a user eye tracking camera communicatively coupled to the processor, an environment camera communicatively coupled to the processor, a feedback device communicatively coupled to the processor, and machine readable instructions stored in the memory module that, when executed by the processor, cause the vision-assist system to receive environment image data from the environment camera, determine a location of an individual speaking to a user based on the environment image data, receive user eye tracking image data from the user eye tracking camera, determine a pose of the user's eyes based on the user eye tracking image data, and provide feedback to the user with the feedback device based on the location of the individual speaking to the user and the pose of the user's eyes.

Abstract: A method and system for servicing streaming media is disclosed. The method includes receiving the streaming media and determining an allocation of available processing and memory resources. In addition, the method includes performing a multi-stage service on the streaming media and caching an intermediate result from one of the stages of the multi-stage process. The intermediate result is selected according to the available processing and memory resources.

Abstract: A microscopy optoelectronic device for reconstructing a three-dimensional model of a sample, which can be connected to any PC in order to obtain three-dimensional surface micro-reliefs, includes a portable device body, having a casing and a frame supporting: a digital optical sensor; an optical group, coupled to the sensor including an objective lens directed towards a distal end of the device body, faceable towards the sample; a motor that translates the optical group and sensor with respect to said frame; a connector to connect the device body to an energy source and to a device that controls the position of the optical group and to transmit the digitalized images; and a light source that provides diffused lighting at the objective lens arranged to surround a front region with respect to the objective lens and also includes a luminescent and diffusing surface having a tubular portion coaxial to the optical group.

Abstract: The present disclosure provides an image encoding/decoding apparatus and method, and a reference picture indexing apparatus and method. The reference picture indexing apparatus includes: a candidate reference picture setting unit for setting candidate reference pictures; a priority order determining unit for determining a priority order of the candidate reference pictures set by the candidate reference picture setting unit, according to a current block to be encoded; and a reference picture indexing unit for adaptively indexing a reference picture according to the current block based on the priority order determined by the priority order determining unit.

Abstract: Data (e.g., images, video, data fields, character strings, logos, etc.) may be analyzed to identify common elements and differentiating elements, and the elements may be respectively transmitted using different streams. For example, if two devices are receiving two video images that are nearly the same, a first data stream comprising the one or more identified common elements may be sent to them both, a second data stream comprising a portion of the one or more identified differentiating elements may be transmitted to the first device, and a third data stream comprising a different portion of the one or more identified differentiating elements may be transmitted to the second device.

Abstract: A system and method are disclosed for determining a depth map using TOF with low power consumption. In order to disambiguate, or de-alias, the returned distance(s) for a given phase shift, the system may emit n different frequencies of light over n successive image frames. After n frames of data are collected, the distances may be correlated by a variety of methodologies to determine a single distance to the object as measured over n image frames. As one frequency may be emitted per image frame, the depth map may be developed while consuming low power.

Abstract: An image capturing apparatus comprises an object detection unit configured to detect a predetermined object and a movement amount acquisition unit configured to acquire an amount of movement of the predetermined object. An object tracking unit suppresses the amount of movement of the predetermined object by moving an optical element constituting an image capturing optical system. A motion vector detection unit detects a motion vector indicating an image blur amount. An image blur correction unit corrects image blur based on the motion vector. A switching unit switches whether or not to perform object tracking using the object tracking unit. The image blur correction unit makes effect of the image blur correction in a case of performing the object tracking smaller than effect of the image blur correction in a case of not performing the object tracking.

Abstract: A microscope system comprises: a stage carrying a sample; an optical system forming an sample image; a driver driving at least the optical system or stage to relatively moves the sample and optical system; an imaging section capturing a reference viewing field image as an image of a predetermined viewing field range of the sample and peripheral viewing field images each being an image of a peripheral viewing field range containing a predetermined region in the predetermined viewing field range and different from the predetermined viewing field range, by the driver moving the relative position of the sample; a correction gain calculator calculating a correction gain of each pixel of the reference viewing field image based on the reference viewing field image and peripheral viewing field image; and a corrector performing shading correction on the reference viewing field image based on the calculated correction gain.

Abstract: The present invention relates to a method, an apparatus, a method and a computer program suitable for controlling a stereoscopic field sequential color display to provide a first primary color component image for a user's first eye and a second primary color component image for the user's second eye, wherein the first and the second primary color component images are both provided either at least partially overlapping in time or alternately in uninterrupted succession and wherein the primary color components of the first and second primary color component images are different from each other.

Abstract: A system prepares plant specimens, tracks the plant specimens, captures images of the plant specimens, and evaluates growth parameters of the plant specimens in the captured images. The system prepares receptacles by placing a predetermined quantity of gel, if required by a particular test, into a receptacle and a layer of material, if required by a particular test, on top of the gel. The system separates a quantity of seeds into individual seeds and places an individual seed in each receptacle between the gel layer and the cover layer. The receptacles are then arrayed into decks and carts and subjected to controlled stress conditions and conditions conducive to germination and growth. An image capture device captures backlit images of the receptacles, and a processor analyzes the captured images for growth parameters of the plant specimens and enters those parameters into a database together with a unique identifier of the plant specimen.

Abstract: Devices, systems and methods for displaying in-vivo images at variable rate. For example, a system includes a processor to gradually increase a frame display rate of an in-vivo image stream based on a similarity among two or more in-vivo frames of the in-vivo image stream.

Abstract: Example embodiments may help multi-camera devices determine disparity information scene, and use the disparity information in an autofocus process. An example method involves: (a) receiving image data of a scene that comprises at least one image of the scene captured by each of two or more image-capture systems of a computing device that includes a plurality of image-capture systems; (b) using the image data captured by the two or more image-capture systems as a basis for determining disparity information for the scene; and (c) performing, by the computing system, an autofocus process based at least in part on the disparity information, wherein the autofocus process provides a focus setting for at least one of the image-capture systems of the computing device.