Abstract: A computer-implemented semantic analysis system for ranking search results has instructions including the steps: receive a query about a first document authored by a person; read in data identifying the first document; read in a second document about the person authored after the first document; identify indicator terms in the second document related to whether or not there is a significant discrepancy between the second document and the first document; read in weighting factors for the identified indicator terms; determine an aggregate weighting factor that decreases with an increasing number of indicator terms found; and calculate a score of how much of a discrepancy there is between the second document and the first document using the weighting factors. When multiple first documents are returned for multiple persons, present the links in order from high score to low score.

Abstract: A thin film vessel useable in gravimetric methods for measuring the total dissolved solids or total solids in a liquid sample, or the moisture content of a solid sample. The vessel includes a main body formed of a thin walled polymeric material having a melting temperature greater than 180° C. The main body comprises an open top edge and a sealed bottom edge which define an inner cavity configured to hold a volume of liquid, and indicia applied to a portion of the main body, wherein the indicia include a tare weight of the vessel.

Abstract: Head-mounted displays (100) are disclosed which include a frame (107), an image display system (110) supported by the frame (107), and a Fresnel lens system (115) supported by the frame (107). The HMD (100) can employ a reflective optical surface, e.g., a free-space, ultra-wide angle, reflective optical surface (a FS/UWA/RO surface) (120), supported by the frame (107), with the Fresnel lens system (115) being located between the image display system (110) and the reflective optical surface (120). The Fresnel lens system (115) can include at least one curved Fresnel lens element (820). Fresnel lens elements (30) for use in HMDs are also disclosed which have facets (31) separated by edges (32) which lie along radial lines (33) which during use of the HMD pass through a center of rotation (34) of a nominal user's eye (35) or through the center of the eye's lens (36) or are normal to the surface of the eye's cornea.

Abstract: A thin film vessel useable in gravimetric methods for measuring the total dissolved solids or total solids in a liquid sample, or the moisture content of a solid sample. The vessel includes a main body formed of a thin walled polymeric material having a melting temperature greater than 180° C. The main body comprises an open top edge and a sealed bottom edge which define an inner cavity configured to hold a volume of liquid, and indicia applied to a portion of the main body, wherein the indicia include a tare weight of the vessel.

Abstract: Embodiments relate to an immersive viewer system and viewer housing. The system comprises a viewer housing having first and second viewing apertures and a device holder. The system includes a first set of Fresnel lenses in-line with the first viewing aperture and a second set of Fresnel lenses in-line with the second viewing aperture. The system may include a computing device having a generally rectangular profile with a narrow depth configured to be supported in the device holder such that a display screen of the computing device is directly viewable through the first and second viewing apertures. The first set and second set of Fresnel lenses bend a two-dimensional (2D) image displayed by the display screen to fully cover 180 degrees of a human field-of-view. The first and second sets of Fresnel lenses are configured to cause the 2D image to appear as a three-dimensional (3D) image.

Abstract: A display assembly (515) includes: (a) an image display system (10) which includes an array of pixels (120) and (b) an array of pixel lenses (115). The array of pixel lenses has each lens positioned to collimate or substantially collimate light from a corresponding single pixel of the array of pixels. The display assembly (515) is used in a head-mounted display apparatus (500) which includes a frame (510) to support the display assembly (515) a desired distance from a user's eyes. The head-mounted display apparatus may also include a beam splitter (520) to reflect images from the display assembly (515) to the user's eyes. The head-mounted display apparatus may provide a wide field of view to the user and may be of the augmented-reality or immersive type.

Abstract: Head-mounted displays (100) are disclosed which include a frame (107), an image display system (110) supported by the frame (107), and a Fresnel lens system (115) supported by the frame (107). The HMD (100) can employ a reflective optical surface, e.g., a free-space, ultra-wide angle, reflective optical surface (a FS/UWA/RO surface) (120), supported by the frame (107), with the Fresnel lens system (115) being located between the image display system (110) and the reflective optical surface (120). The Fresnel lens system (115) can include at least one curved Fresnel lens element (820). Fresnel lens elements (30) for use in HMDs are also disclosed which have facets (31) separated by edges (32) which lie along radial lines (33) which during use of the HMD pass through a center of rotation (34) of a nominal user's eye (35) or through the center of the eye's lens (36) or are normal to the surface of the eye's cornea.

Abstract: Aspects of the disclosure provide an apparatus for image displaying. The apparatus includes a prediction system and an imaging system. The prediction system is configured to predict, for a first time, a first position of a display device at a specific future time for displaying an image associated with a position of the display, and predict, for a second time that is later than the first time, a second position of the display at the future time with an offset to the first position. The imaging system is configured to render a first image associated with the first position, buffer the first image in a memory, and adjust the buffered first image according to the offset to generate a second image associated with the second position of the display device.

Abstract: Head-mounted displays (100) are disclosed which include a frame (107), an image display system (110) supported by the frame (107), and a Fresnel lens system (115) supported by the frame (107). The HMD (100) can employ a reflective optical surface, e.g., a free-space, ultra-wide angle, reflective optical surface (a FS/UWA/RO surface) (120), supported by the frame (107), with the Fresnel lens system (115) being located between the image display system (110) and the reflective optical surface (120). The Fresnel lens system (115) can include at least one curved Fresnel lens element (820). Fresnel lens elements (30) for use in HMDs are also disclosed which have facets (31) separated by edges (32) which lie along radial lines (33) which during use of the HMD pass through a center of rotation (34) of a nominal user's eye (35) or through the center of the eye's lens (36) or are normal to the surface of the eye's cornea.

Abstract: Head-mounted displays (100) are disclosed which include a frame (107), an image display system (110) supported by the frame (107), and a Fresnel lens system (115) supported by the frame (107). The HMD (100) can employ a reflective optical surface, e.g., a free-space, ultra-wide angle, reflective optical surface (a FS/UWA/RO surface) (120), supported by the frame (107), with the Fresnel lens system (115) being located between the image display system (110) and the reflective optical surface (120). The Fresnel lens system (115) can include at least one curved Fresnel lens element (820). Fresnel lens elements (30) for use in HMDs are also disclosed which have facets (31) separated by edges (32) which lie along radial lines (33) which during use of the HMD pass through a center of rotation (34) of a nominal user's eye (35) or through the center of the eye's lens (36) or are normal to the surface of the eye's cornea.

Abstract: A thin film vessel useable in gravimetric methods for measuring the total dissolved solids or total solids in a liquid sample, or the moisture content of a solid sample. The vessel includes a main body formed of a thin walled polymeric material having a melting temperature greater than 180° C. The main body comprises an open top edge and a sealed bottom edge which define an inner cavity configured to hold a volume of liquid, and indicia applied to a portion of the main body, wherein the indicia include a tare weight of the vessel.

Abstract: A system a 3D scanning device located at a first location configured to capture information for a 3D model of an object, a first computing system located at a second location configured to provide for an annotation of an augmented reality image on the 3D model, a second computing system located at the first location configured create the 3D model and to illustrate the annotation of the augmented reality image or the annotation of the augmented reality image on the 3D model created at the second location, and a communication protocol configured to communicate the 3D model and the augmented reality image between the first computing system and the second computing system. A method is disclosed. A non-transitory processor readable storage medium, providing an executable computer program product, the executable computer program product comprising a computer software code when executed causes a processor to perform certain functions is also disclosed.

Abstract: A system and method for reduction of chromatic aberration for an image projection system utilizes a computer system that processes a parametric equation that defines the physical parameters of a projection lens unit. Based on the parametric equation, the divergence or refractive induced bending of light rays passing through the lens unit is identified. This divergence data is then utilized to generate offset values that are transferred to a control unit of a digital image display unit so as to offset, or otherwise space apart, the position of specific color sub-pixels by an appropriate amount to compensate for the divergence or bending effects of the lens unit. The applied offset causes the color light rays emitted by the color pixels to converge or otherwise join after passing through the lens, thus eliminating, or otherwise minimizing the chromatic aberration associated with the projected image.

Abstract: An auto-stereoscopic display which includes a screen substrate having a first face and a second face. A lenticular array having a plurality of lenticules extending in a first direction and a second direction is affixed to the first face. A plurality of first elongated light filters is affixed to the second face. The first elongated light filters extend parallel to the plurality of lenticules and are adapted to pass light waves having a first orientation. A plurality of second elongated light filters extending parallel to the plurality of lenticules is affixed to the second face and adapted to pass light waves having a second orientation.

Abstract: Computer-based methods and associated computer systems are disclosed for designing free space reflective optical surfaces (13) for use in head-mounted displays (HMDs). The reflective optical surface (13) produces a virtual image of a display surface (11) for viewing by a user's eye (15). The method includes using one or more computers to: (i) represent the display surface (11) by display objects (25); (ii) represent the free space reflective optical surface (13) by surface elements (23); and (iii) iteratively calculate spatial locations, normals, and radii of curvature for the surface elements (23) which will cause a virtual image of each display object (25) to be displayed to a nominal user's eye (15) in a desired direction of gaze of the eye (15).

Abstract: Systems, apparatus, and methods are provided which: (a) receive wired or wireless transmission of information regarding an orientation of a weapon; (b) receive wired or wireless transmission of information regarding an orientation of a viewing area of a head-mounted display apparatus; (c) process ballistic information of ammunition to be fired by the weapon and the information regarding the orientations of the weapon and the viewing area to obtain a calculated endpoint of the ammunition to be fired by the weapon; and (d) display an icon (e.g., a crosshair) representative of the endpoint of the ammunition in the viewing area of the head-mounted display apparatus.

Abstract: Head-mounted displays (100) are disclosed which include a frame (107), an image display system (110) supported by the frame (107), and a reflective surface, e.g., a free-space, ultra-wide angle, reflective optical surface (a FS/UWA/RO surface) (120), supported by the frame (107). In certain embodiments, the reflective surface (120) produces spatially-separated virtual images that are angularly separated by at least 100, 150, or 200 degrees. Methods and apparatus for designing reflective optical surfaces, including FS/UWA/RO surfaces, for use in head-mounted displays (100) are also disclosed.

Abstract: An input device configured to control a communicatively coupled remote processor is disclosed. The input device includes a band that is configured to at least partially encircle a digit of a hand. A connection member suspends a platform above an exterior surface of the band. The platform is configured to be manipulated by a second digit of the hand. A processor is configured to determine event data based on the manipulation of the platform. The event data is transmitted via a radio frequency (RF) transmitter in a control signal to the communicatively coupled remote processor.

Abstract: A display assembly (515) includes: (a) an image display system (10) which includes an array of pixels (120) and (b) an array of pixel lenses (115). The array of pixel lenses has each lens positioned to collimate or substantially collimate light from a corresponding single pixel of the array of pixels. The display assembly (515) is used in a head-mounted display apparatus (500) which includes a frame (510) to support the display assembly (515) a desired distance from a user's eyes. The head-mounted display apparatus may also include a beam splitter (520) to reflect images from the display assembly (515) to the user's eyes. The head-mounted display apparatus may provide a wide field of view to the user and may be of the augmented-reality or immersive type.

Abstract: An exoskeleton that typically provides human power and endurance augmentation is adapted for use with a simulator system that generates a virtual environment by accepting and processing commands from the simulator to implement gross motor virtual feedback in which some motions of the exoskeleton's wearer (called the “pilot”) are constrained by the exoskeleton to simulate the interaction of the pilot with virtual objects in the virtual environment. In this way, the pilot can interact with virtual objects generated by the simulator system not only visually but through touch as well. For example, a pilot in a combat simulation can move along a virtual wall by feel while maintaining cover from enemy fire and perform actions like pushing virtual objects to clear obstacles from a path.