Abstract: An augmented reality (AR) vision system is disclosed. A display is configured to present a surrounding environment to eyes of a user of the AR vision system. A depth tracker is configured to produce a measurement of a focal depth of a focus point in the surrounding environment. Two or more image sensors receive illumination from the focus point and generate a respective image. A controller receives the measurement of the focal depth, generates an interpolated look-up-table (LUT) function by interpolating between two or more precalculated LUTs, applies the interpolated LUT function to the images to correct a parallax error and a distortion error at the measured focal depth, generates a single image of the surrounding environment, and displays the single image to the user.

Abstract: A computer system with an augmented reality display renders one or more virtual training elements in a real world environment. Cameras analyze the local real-world environment to produce a detailed terrain map which is used to more accurately locate the virtual training elements. The cameras also track the movement of the trainee by recognizing terrain features and deriving such movement based on changes from one scan to the next, and potentially based on GPS and inertial management unit data. A centralized computer system correlates terrain maps from a plurality of trainees and defines real-world locations for virtual training elements, then transmitting the virtual training elements to the plurality of trainees.

Abstract: An image processing system incorporates a distortion correction (DC) sub-system in order to quickly correct skewed images. The DC sub-system includes a buffer, a processor and a sparse matrix table (SMT). The buffer is sized according to an amount of distortion in an input image. Input image pixels from an input frame are buffered in the buffer, and other input image pixels from the same frame overwrite the buffered input image pixels, reducing latency of the DC sub-system. The SMT is dynamically configurable and provides mapping values for mapping output pixels to input pixels. The processor implements combinational logic, including multipliers, lookup tables and adders. The combinational logic interpolates flow control parameters, pixel coordinate values, and pixel intensity values. The distortion correction values are streamed to a display or provided to a subsequent image processing block for further processing.

Abstract: A low-latency method for applying image processing steps includes processing and displaying portions of the image as they are received in real-time. In a denoising process, the portion is denoised by selecting pixels, establishing a block centered on each pixel, identifying similar blocks within the portion, and performing a filtering process such as hard thresholding before the entire image is received. Pixels within each block may also be averaged.

Abstract: A method for routing of information between networks of differing security levels may include, but is not limited to: receiving a data packet from a first network having a security classification at a first network node; determining a geographic location of the first network node; applying one or more geographic location-dependent access control rules for the data packet according to the geographic location of the first network node with a guard engine; transferring the data packet to a second network according to compliance of the data packet with the one or more geographic location-dependent access control rules.

Abstract: A method and related system is disclosed for integrating a positioning system into the key management structure and within the information security boundary of an End Cryptographic Unit (ECU). This integration enables key management security rules written to include the ECU's trusted physical location and trusted time in determining if and with which key a message should be encrypted or decrypted. Only appropriate messages for a bounded geographic area would be decrypted and received by the ECU. The trusted positioning system allows extending functionality to allow position-enhanced authentication capabilities. Outgoing messages are cryptographically bound with the ECU's trusted position information as well as an accurate time stamp.

Abstract: Force feedback elements are incorporated at various points in a flight helmet. An onboard computer system identifies critical events and translates such events into a force feedback pulse applied to one or more of the force feedback elements, warning the pilot of the critical event while at the same time suppressing more conventional critical event warnings that may distract a pilot. Additionally, force feedback elements are incorporated into a vest, bodysuit or body armor. A mobile, personal computer system applies a force feedback pulse to one or more of the force feedback elements to indicate an event that might otherwise require an audible signal.