Abstract: Stereoscopic imaging is performed using a mobile computing device having front- and rear-facing cameras and mounted on a rotational mechanism. The cameras and rotational mechanism are controlled, e.g., by a downloaded application, to capture images of a room or other environment using both the front- and rear-facing cameras at different pan angle and tilt angle combinations. First and second images of a portion of the room or other environment, captured using the front- and rear-facing cameras, are selected for inclusion in a stereo image pair. Obtained images and corresponding metadata are transferred to a remote system. A structure from motion pipeline is used to generate a three-dimensional model of the room or other environment. Data that enables the mobile computing device to display a three-dimensional model of the room or other environment is received from the remote system and used to display the three-dimensional model.

Abstract: A method and device for encoding or decoding a picture block having a luminance component. The method includes obtaining a luminance residual block (Lr) by subtracting a first representation (Ll, LlD) of an average value of the luminance component calculated from the luminance component, obtaining a second representation (ƒ(Ll), ƒ(Ll)D) of the average value by applying a transfer function to the average value (Ll) of the luminance component in order to reduce the dynamic range of the average value and encoding a luminance block (Le) obtained by adding (105, 302) together the luminance residual block (Lr) and the second representation (ƒ(Ll), ƒ(Ll)D) of the average value.

Abstract: An imaging device includes an image sensor, an optical system forming an image of an object on the image sensor, and a processor. The optical system switches between a first state of capturing an image of the object with a single pupil and a second state of capturing an image of the object with two pupils. The processor generates a simulative phase difference image from a first captured image captured with the image sensor in the first state, and executes matching processing of comparing the simulative phase difference image with a second capture image captured with the image sensor in the second state to detect a phase difference between an image formed with one of the two pupils and an image formed with another one of the two pupils.

Abstract: A video encoding device 10 includes: an entropy encoding unit 11 for entropy-encoding at least a quadtree split flag, a skip flag, a binary tree split flag, and a binary tree split direction flag; and an entropy encoding control unit 12 for controlling the entropy encoding unit 11, wherein the entropy encoding control unit 12, in the case where the skip flag of a block of an end node in a quadtree structure indicates that the binary tree split flag succeeds, causes the entropy encoding unit 11 to entropy-encode the binary tree split flag and the binary tree split direction flag, and in the case where the skip flag of the block oft the end node in the quadtree structure indicates that the binary tree split flag does not succeed, causes the entropy encoding unit 11 not to entropy-encode the binary tree split flag and the binary tree split direction flag.

Abstract: An endoscope or exoscope having a shaft and at least one objective and at least one electronic image recorder for recording an image of an object field, wherein the objective and image recorder are arranged in a distal end region of the endoscope or exoscope, and includes at least one cable, routed within the endoscope or exoscope, for supply of and/or image transmission from the electronic image recorder, wherein the electronic image recorder includes an optical unit, which is rotatable about a first axis of rotation identical or approximately parallel to a direction of view of the scope, and on which the cable is connected and can be wound on a circumferential surface of the optical unit, and wherein the distal end region includes a cavity, in which storage for holding a section of the cable is held.

Abstract: A method of an image sensor device includes: using a pixel array of the image sensor device to sense and generate at least one dark image; computing pixel statistics according to the at least one dark image; and, determining which one of a plurality of temperature ranges a temperature of the image sensor device falls within according to the pixel statistics.

Abstract: A multi-layer encoder/decoder system is provided that uses base layer intra mode for enhancement layer intra mode prediction. The encoder provides the base layer intra mode in the base layer of a two layer video encoder, and uses the base layer intra mode as one of a plurality of most probable modes (MPMs). Then in determining the enhancement layer intra mode, the MPMs are used.

Abstract: A low earth orbiting spacecraft (LEO spacecraft) operable in a first earth orbit includes a main body, a data collection payload, and a first directional antenna, each of the data collection payload and the first directional antenna being coupled with the main body. During a first period of time, the main body is oriented such that the data collection payload views a region of interest on the earth. During a second period of time, the main body and the first directional antenna are oriented such that the first directional antenna is directed toward a first ground station. During a third period of time, the main body and the first directional antenna are oriented such that the first directional antenna is directed toward a second spacecraft operating in a second orbit.

Abstract: In one example, a device for coding video data includes a video coder configured to configured to code information representative of whether an absolute value of an x-component of a motion vector difference value for a current block of video data is greater than zero, code information representative of whether an absolute value of a y-component of the motion vector difference value is greater than zero, when the absolute value of the x-component is greater than zero, code information representative of the absolute value of the x-component, when the absolute value of the y-component is greater than zero, code information representative of the absolute value of the y-component, when the absolute value of the x-component is greater than zero, code a sign of the x-component, and when the absolute value of the y-component is greater than zero, code a sign of the y-component.

Abstract: An entropy encoding control unit 13, in the case where the skip flag of a block of an end node in a quadtree structure indicates that the binary tree split flag succeeds, causes the entropy encoding unit 11 to entropy-encode the binary tree split flag and the binary tree split direction flag, and in the case where the skip flag of the block of the end node in the quadtree structure indicates that the binary tree split flag does not succeed, causes the entropy encoding unit 11 not to entropy-encode the binary tree split flag and the binary tree split direction flag, and in the case where a node of a size equal to the minimum size is further partitioned based on the binary tree structure, causes the entropy encoding unit 11 not to entropy-encode the binary tree split direction flag at the node.

Abstract: An image generation device includes an imaging unit 11, a projection unit 22, and a distance information generation unit 18, and a projection pattern includes unit patterns arranged in a plurality of rows in a first direction and in a plurality of columns in a second direction. A plurality of light dots include first dots and second dots which are light dots of different states from each other; the unit patterns arranged in the first direction have the light dot arrangements identical with each other; the unit patterns arranged in the second direction have light dot arrangements different from each other; the number of first dots among a plurality of light dots arranged in the first direction in each of the unit patterns is the same fixed number in each row in the second direction; and in a location other than the unit pattern, the number of first dots included in a row of the same length as the unit pattern in the second direction differs from the fixed number, in a certain row in the second direction.

Abstract: Various implementations include an occupant monitoring system (OMS) for monitoring at least one occupant in a vehicle. The OMS includes a mounting bracket coupled to a rotatable portion of a steering wheel assembly, a housing coupled to the mounting bracket, at least one imaging unit disposed within the housing, and at least one lens disposed adjacent the housing and imaging unit and facing an expected position of at least one vehicle occupant and configured for allowing light to pass through to the imaging unit. The mounting bracket extends upwardly from the steering wheel assembly adjacent a central portion thereof. The housing has a back surface that is disposed adjacent a back cover of the steering wheel assembly. The imaging unit has a field of view inside of the vehicle and is configured to capture an image signal corresponding to an imaging area within the field of view.

Abstract: A device for decoding video data includes a memory configured to store video data and a video decoder comprising one or more processors configured to adaptively select motion vector precision for motion vectors used to encode blocks of video data.

Abstract: Automated operations may be performed involving acquiring and analyzing information from an interior of a house, building or other structure, for use in generating and providing a representation of that interior. Such operations may include using a user's mobile device to capture video data from multiple viewing locations (e.g., 360° video at each viewing location) within multiple rooms, and capturing data linking the multiple viewing locations (e.g., by recording video, acceleration and/or other data from the mobile device as the user moves between the two viewing locations), creating a panorama image for each viewing location, analyzing the linking information to model the user's travel path and determine relative positions/directions between at least some viewing locations, creating inter-panorama links in the panoramas to each of one or more other panoramas based on such determined positions/directions, and providing information to display multiple linked panorama images to represent the interior.

Abstract: A vision system for a vehicle includes side and rear cameras that are operable to capture image data. The rear camera is configured to be disposed at a rear portion of the vehicle so as to have a rearward field of view and the side cameras are configured to be disposed at respective side portions of the vehicle so as to have respective sideward and rearward fields of view. The rear camera has a rear imager and a wide angle lens, which is disposed at the rear imager with its center axis offset from a center region of the rear imager so as to be disposed at and to image at an upper region of the rear imager. An image processor processes captured image data to merge captured image data to provide a panoramic image for display to the driver during a reversing maneuver of the vehicle.

Abstract: Methods and apparatus for Real-time Satellite Imaging System (10) are disclosed. More particularly, one embodiment of the present invention an imaging sensor (14) on a geostationary satellite having one or more co-collimated telescopes (18). The telescopes (18) illuminate focal planes (22) which are sparsely populated with focal plane arrays (24). The focal plane arrays (24) record the entire observable Earth hemisphere at one time, at least once every ten seconds, or more often.

Abstract: Embodiments of the present disclosure include a system and a method of accessing a system. An embodiment is a system including an imaging system including a controller and a first camera, the controller having a communication connection configured to transmit or receive content or control signals, and a mobile device including a second camera, the mobile device having a communication interface configured to transmit or receive content or control signals with the controller, the controller being configured to compare images from the first and second cameras to allow access to the controller from the mobile device.

Abstract: A vehicle rear monitoring system includes a camera that captures an image of an area to a rear of a vehicle, and a processing unit that processes the image captured by the camera. The processing unit creates a first vehicle rear image that is displayed in a first display area that is a portion of a display area of a display device, when traveling forward, and creates a second vehicle rear image that is displayed in a second display area that is within the display area of the display device and that is an area that includes the first display area and is larger than the first display area, when traveling backward.

Abstract: A vision system for a vehicle includes at least one camera having a field of view exterior the vehicle. An image processor is operable to process image data captured by the camera. When the vehicle is parked, a control controls the camera to capture frames of image data at a first capture rate. The control compares a frame of captured imaged data to at least one previous frame of captured image data. Responsive to the comparison determining a change in the frames of captured image data beyond a threshold degree of change, (i) the control increases the capture rate to a second capture rate, (ii) the at least one camera captures frames of image data at the second capture rate and (iii) the control activates a recording device to record images captured by the camera at the second capture rate.

Abstract: Control data for a motion-constrained tile set (“MCTS”) indicates that inter-picture prediction processes within a specified set of tiles are constrained to reference only regions within the same set of tiles in previous pictures in decoding (or encoding) order. For example, a video encoder encodes multiple pictures partitioned into tiles to produce encoded data. The encoder outputs the encoded data along with control data (e.g., in a supplemental enhancement information message) that indicates that inter-picture prediction dependencies across tile set boundaries are constrained for a given tile set of one or more of the tiles. A video decoder or other tool receives the encoded data and MCTS control data, and processes the encoded data. Signaling and use of MCTS control data can facilitate region-of-interest decoding and display, transcoding to limit encoded data to a selected set of tiles, loss robustness, parallelism in encoding and/or decoding, and other video processing.