Abstract: One variation of a first method for collecting and sharing substantially real-time video feeds of employees within a distributed workforce includes: distributing a first subset of employee video feeds to a first instance of an employee portal; distributing a second subset of employee video feeds to a second instance of the employee portal; distributing the manager video feed to the first instance and the second instance of the employee portal; distributing the set of employee video feeds to an instance of the manager portal; in response to initiation of a recess for the first employee: replacing the first employee video feed with a recess icon in the second instance of the employee portal and the instance of the manager portal; initiating a timer for the recess; and in response to expiration of the timer, reactivating the first employee video feed.

Abstract: The present aspects relate to techniques of timing synchronization of audio and video (AV) data in a network. In particular, the techniques for a AV master to distribute AV data encoded with one or more time markers to a plurality of processing nodes. The one or more time markers may be indexed to a precision time protocol (PTP) time stamp used as a time reference. In one technique, the nodes extract the time markers to determine an offset value that is applied to a PLL to synchronize AV data packets at a distribution node or a processing node. In another technique the distribution node or the processing node determines the worst case path, which corresponds to a system offset value. The distribution node then reports the system offset value to the AV master, which in turn adjusts the phase based on the report.

Abstract: A receiving device for reducing video latency includes a display render unit, a communication interface, a memory, and a processor. The display render unit performs a video transmission to output a video to a display apparatus. The video generated by a video capture unit of the sending device is transmitted through the communication interface to the receiving device. The memory stores at least one computer readable instruction. The processor accesses and executes the at least one computer readable instruction to: determine whether a video latency is necessary to be reduced; determine a target reduced latency based on a target line count and a current line count; and determine a first period based on the target reduced latency and an accelerating scheme at the display render unit. The display render unit performs the video transmission to the display apparatus based on the accelerating scheme for the first period.

Abstract: A method for separating layers in an image using image processing, comprising: identifying a non-repeating pattern depicted in a captured image, the non-repeating pattern comprising a plurality of graphic elements, having a different chroma and luma; defining a transformation between an original version of the non-repeating pattern stored in a memory and the non-repeating pattern depicted in the captured image; and removing the non-repeating pattern from the captured image by using the transformation, to be replaced by a target image.

Abstract: An image display apparatus has: an imaging device (11L, 11R) that is placed at a tiltable housing (15L, 15R) and that is configured to image a rear side area (BL_area, BR_area) of a vehicle (1), the housing being allowed to rotate around a predetermined rotational axis (?L, ?R) that is along a direction inclined to a yaw axis of the vehicle; and a displaying device (14) that is configured to display an external image captured by the imaging device.

Abstract: Devices and methods for determining image quality using full-reference and non-reference techniques. Full reference image quality may be determined prior to output of an image or video frame from an image sensor processor by temporarily retaining image data from the image sensor and comparing processed image data of the image to the retained, non-processed image data of the same image. Full reference image quality determination may be assisted by a heuristic-based fault indicator. Image quality may also be determined by a non-reference technique of matching the image to one of various scenarios that are associated with sets of heuristics and applying the heuristics of the particular scenario to the image. Instead of relying on a nominal frame rate, video timing quality may be determined by comparing the capture time interval between successive video frames to the presentation time interval of the same video frames.

Abstract: A system for adjusting the display of a digital display device comprising a digital display device including a display, a receiver, and a display controller, an object having a communication device that wirelessly communicates with the receiver, wherein the display controller automatically adjusts the display of the digital display device based on the communication.

Abstract: An optical module includes a light modulator that modulates light and includes a plurality of pixels, and a pixel shift mechanism. The light modulator is driven based on an interlace method. The pixels of the light modulator each include a first sub-pixel on which a first color light flux or a second color light flux is incident, a second sub-pixel on which a color light flux different from the color light flux incident on the first sub-pixel out of the first color light flux and the second color light flux is incident, and a third sub-pixel and a fourth sub-pixel on which a third color light flux is incident. The third sub-pixel and the fourth sub-pixel are arranged in a scan direction of the light modulator. The pixel shift mechanism shifts the light modulator in a direction that intersects the scan direction.

Abstract: A method for automatically adjusting display parameters of a display screen of a television device includes: in receipt of an activation signal, controlling the display screen to output a video signal based on a set of display parameters, and controlling the depth camera to capture images of a viewing area; determining a set of condition parameters based on the images; determining, based on the set of condition parameters, whether the video signal is to be adjusted; and when it is determined that the video signal is to be adjusted, adjusting at least one display parameter in the set of display parameters to generate an adjusted video signal and controlling the display screen to output the adjusted video signal.

Abstract: The present invention provides a modular display system that uses Ethernet connection to directly send control and display data to each display module. The modular display system includes a master control unit and a plurality of display modules that are arranged and connected together to create a larger unified display. The control unit is connected to the display modules to send display and control data, and to receive diagnostic data, all via Ethernet connection. In some embodiments, each display module has an input Ethernet connection for upstream communication and an output Ethernet connection for downstream communication. The modules in this configuration are connected together in a daisy-chain fashion and Ethernet connection between the control unit and display modules creates a local area network (LAN) where all modules are addressable by the control unit and relevant data can be transferred.

Abstract: A display system for calibrating a displayed image includes a monitor device and a calibration device. The monitor device is used for displaying a calibration interface when an image calibration process is performed. The calibration device is coupled to the monitor device for selecting a calibration mode through the calibration interface. The calibration interface includes at least one calibration mode. The calibration device selects and confirms the calibration mode from the at least one calibration mode by using at least one key.

Abstract: A device may receive initial registration data identifying initial camera parameters associated with a camera device provided at a location, and may receive location data associated with the location captured by the camera device. The device may receive map data identifying a map image of the location, and may transform the initial registration data into estimated camera parameters. The device may process the location data, with the estimator model, to generate extracted data, and may process the estimated camera parameters, the extracted data, and the map data, with a parameter optimization model, to identify camera parameters for the camera device. The device may provide the camera parameters to the camera device to cause the camera device to be configured based on the camera parameters.

Abstract: A method and apparatus for determining a location and/or orientation of at least a portion of an electric vehicle relative to at least a portion of a charging station. A camera system can include a camera housing having outer, intermediate, and inner layers that are concentric to each other. The outer, protective layer and the intermediate layer can each have wiper assemblies that wipe debris from a surface of the intermediate layer or inner layer, respectively, as the associated outer or intermediate layer is rotated. The intermediate layer also include one or more lenses that are selectively to capture an image(s) of the vehicle by a camera. The camera housing can be lifted from a recessed position in an assembly housing while the outer layer is simultaneously rotatably retracted so that the camera can capture an image through the inner layer and a selected lens of the intermediate layer.

Abstract: Alight source apparatus includes a light source, a first polarization separator that transmits a first polarization component of first light in the first direction and reflects a second polarization component of the first light in a second direction, a second polarization separator that reflects the first polarization component of the first light in the second direction, a first reflector that reflects the second polarization component of the first light, a first retarder between the first polarization separator and the first reflector, a wavelength converter that converts the first light into second light and outputs the second light, a first color separator, a second retarder, a second color separator, and a third retarder.

Abstract: Techniques for automated up-sampling of media files are provided. In some examples, a title associated with a media file, a metadata file associated with the title, and the media file may be received. The media file may be partitioned into one or more scene files, each scene file including a plurality of frame images in a sequence. One or more up-sampled scene files may be generated, each corresponding to a scene file of the one or more scene files. An up-sampled media file may be generated by combining at least a subset of the one or more up-sampled scene files. Generating one or more up-sampled scene files may include identifying one or more characters in a frame image of the plurality of frame images, based at least in part on implementation of a facial recognition algorithm including deep learning features in a neural network.

Abstract: A camera assembly for depth sensing of a local area. The camera assembly includes a projector, a sensor and a controller. The projector emits, into the local area, a structured light (SL) pattern at multiple phases. The sensor images the local area using multiple augmented pixels. Each augmented pixel has multiple gates and at least some of the gates have a respective local storage location. Each capture phase of the augmented pixel is divided into a respective plurality of time bins associated with a respective subset of the gates. Each local storage location of the subset of gates stores image data during a respective time bin, the image data based on portions of the SL pattern emitted at a respective phase and reflected from the local area. The controller determines depth information for the local area based on the image data stored during at least one capture phase.

Abstract: A projective MEMS device, including: a fixed supporting structure made at least in part of semiconductor material; and a number of projective modules. Each projective module includes an optical source, fixed to the fixed supporting structure, and a microelectromechanical actuator, which includes a mobile structure and varies the position of the mobile structure with respect to the fixed supporting structure. Each projective module further includes an initial optical fiber, which is mechanically coupled to the mobile structure and optically couples to the optical source according to the position of the mobile structure.

Abstract: Approaches for dynamically allocating CPU cycles for use in processing a video stream. Video complexity information for two or more digital video streams actively being processed by one or more video encoders is determined at periodic intervals. Video complexity information describes the complexity of digital video carried by the digital video streams across a bounded number of consecutive digital frames which includes digital frames not yet processed by the one or more video encoders. A determination is made as to whether a number of CPU cycles allocated for processing a particular digital video stream should be adjusted based on the determined video complexity information. The number of CPU cycles allocated for processing the particular digital video stream may be dynamically adjusted by changing an amount of CPU cycles allocated to a virtual machine in which the stream is processed or by processing the stream in a different virtual machine.

Abstract: Adaptive imaging methods and systems for generating enhanced low light video of an object for medical visualization are disclosed and include acquiring, with an image acquisition assembly, a sequence of reference frames and/or a sequence of low light video frames depicting the object, assessing relative movement between the image acquisition assembly and the object based on at least a portion of the acquired sequence of reference video frames or the acquired sequence of low light video frames, adjusting a level of image processing of the low light video frames based at least in part on the relative movement between the image acquisition assembly and the object, and generating a characteristic low light video output from a quantity of the low light video frames, wherein the quantity of the low light video frames is based on the adjusted level of image processing of the low light video frames.

Abstract: Systems and methods for using a touch screen are provided herein. In some exemplary embodiments, the touch screen is used as a backup remote to a display and can be used as a 3D pointing device. The touch screen can be an overlay on display surface to control the display. Alternatively, the touch screen can be retractable and ejectable from the display housing. In addition, the touch screen can be wearable. Further, the touch screen can function to control one or more devices, e.g., television, set-top box, DVR, gaming consoles.