Abstract: Embodiments are directed to a mobile application that enables a completely and dynamically configurable workflow. Once installed on a mobile computer, the application is completely configurable without re-compiling the application. A user may configure the “look & feel,” as well as the workflow of a particular instance of the application, via configuration templates. Once the application is downloaded and installed in an executable form, the user may configure and/or reconfigure the workflow and the “look and feel” of the application without a re-compiling operation and/or generating new machine-code to enable the configuration. To configure and/or reconfigure the application, the user need only to edit and/or receive additional configuration templates. The execution of the configured workflow is not dependent upon the mobile computer being in communication with another network computer. The mobile application may be a native application.

Abstract: Embodiments are directed to a mobile application that enables a completely and dynamically configurable workflow. Once installed on a mobile computer, the application is completely configurable without re-compiling the application. A user may configure the “look & feel,” as well as the workflow of a particular instance of the application, via configuration templates. Once the application is downloaded and installed in an executable form, the user may configure and/or reconfigure the workflow and the “look and feel” of the application without a re-compiling operation and/or generating new machine-code to enable the configuration. To configure and/or reconfigure the application, the user need only to edit and/or receive additional configuration templates. The execution of the configured workflow is not dependent upon the mobile computer being in communication with another network computer. The mobile application may be a native application.

Abstract: A method of designing lenses includes defining a material having an inside reflective surface spanning an area, and providing an optical design algorithm which defines a plurality of oxels across the area. Each oxel has a plurality of sub-elements including a center sub-element and a plurality of neighboring sub-elements. Based on a defined optical prescription for the inside reflective surface, an optically corrected reference 3D surface is calculated for each oxel having spherical and cylindrical corrections relative to a spherical contour which spans a predetermined field of view (FOV) with respect to a single (common) predetermined reference point. A position of at least a first of the sub-elements for each of the oxels is moved to approach respective final 3D positions on the optically corrected reference 3D surface, where the moving is constrained to be along an individual line connecting each of the first sub-elements to the single predetermined reference point.

Abstract: A head mounted display (HMD)-based training tool includes a HMD, sensor components, and electronics components. The sensor components include an external environment sensor for obtaining data of a real training scene. The electronics components include a simulator including at least one processor coupled to receive the real training scene data. The simulator generates virtual image data based on simulator input signals, where the virtual image data represents at least one virtual object. A display device is coupled to receive the virtual image data from the simulator. A field of view (FOV) of the HMD includes the virtual object from the display device and a real-world view of the real training scene, wherein the simulator modifies the virtual image data responsive to changes in the simulator input signals.

Abstract: A platform receives service requests from a principal. The service request includes a service location that is remote from the principal. A communication session between the principal and an agent that is near the service location is provided. The agent is available to perform the service, which may include remote videography services, tutorial services, or personal shopping services, over the communication session. The principal generates gesture data to direct the agent when performing the service. A visual representation of the gesture data is provided to the agent so that the agent may follow the principal's direction. The gesture data may be blended and/or overlaid image data captured by an image sensor employed by the agent. The principal may provide financial resources to the agent to enable the agent to perform the service and/or compensate the agent for their performance. The principal is enabled to provide metrics for the agent's performance.

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: A system is disclosed including a mountable component configured with an attachment to allow the mountable component to be readily attached to and removed from an independent wearable garment, a positioning slide connected to the mountable component, a display mount connected to the positioning slide, a lens adjustment arm attached to the positioning slide, and a curved lens surface connected to the lens adjustment arm. The positioning slide is configured to move the lens and display mount in a back and forth direction and a left to right direction. Another system and method are also disclosed.

Abstract: A platform receives service requests from a principal. The service request includes a service location that is remote from the principal. A communication session between the principal and an agent that is near the service location is provided. The agent is available to perform the service, which may include remote videography services, tutorial services, or personal shopping services, over the communication session. The principal generates gesture data to direct the agent when performing the service. A visual representation of the gesture data is provided to the agent so that the agent may follow the principal's direction. The gesture data may be blended and/or overlaid image data captured by an image sensor employed by the agent. The principal may provide financial resources to the agent to enable the agent to perform the service and/or compensate the agent for their performance. The principal is enabled to provide metrics for the agent's performance.

Abstract: A platform receives service requests from a principal. The service request includes a service location that is remote from the principal. A communication session between the principal and an agent that is near the service location is provided. The agent is available to perform the service, which may include remote videography services, tutorial services, or personal shopping services, over the communication session. The principal generates gesture data to direct the agent when performing the service. A visual representation of the gesture data is provided to the agent so that the agent may follow the principal's direction. The gesture data may be blended and/or overlaid image data captured by an image sensor employed by the agent. The principal may provide financial resources to the agent to enable the agent to perform the service and/or compensate the agent for their performance. The principal is enabled to provide metrics for the agent's performance.

Abstract: A lens includes a material spanning an area and providing an inside reflective three-dimensional (3D) surface. The reflective 3D surface is defined by a plurality of reflective optical elements including a first reflective optical element and at least a second reflective optical element that each include a sub-element set including a center sub-element (CS) and a plurality of neighboring sub-elements. The plurality of reflective optical elements each have their own non-overlapping optical center axis; and a cylindrically bent spherical surface. The cylindrically bent spherical surface is defined by the neighboring sub-elements in each reflective optical element being located at different 3D points so that the reflective optical elements relative to at least one neighboring reflective optical element provides different values of spherical curvature and different values of cylindrical axis orientation.

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: An optical system is provided. The optical system includes a lens element and a lens element holder. The optical system also includes a display device holder that is configured to hold a display device having a single light-emitting panel. The lens element includes a right-eye reflective surface and a left-eye reflective surface. The right-eye reflective surface includes a first plurality of different surface elements oriented to reflect and collimate light from corresponding different regions of a first portion of the light-emitting panel toward a predetermined right-eye location, and the left-eye reflective surface includes a second plurality of different surface elements oriented to reflect and collimate light from corresponding different regions of a second portion of the light-emitting panel toward a predetermined left-eye location.

Abstract: A see-through augmented reality system is disclosed. The system includes a head-wearable frame and a lens. The lens has at least one field-of-view (FOV). A sensor is configured to be coupled with respect to a head of a user. The sensor generates sensor data that changes responsive to movements of the head. A display apparatus is mapped to an interior surface of the lens. A controller is coupled to the sensor and to the display apparatus. The controller is configured to determine a current scene within the FOV based at least in part on the sensor data. The controller determines an out-the-window (OTW) scene portion of the current scene and a non-OTW scene portion of the current scene and generates OTW imagery that depicts the OTW scene portion. The controller causes the display apparatus to emit light in accordance with the OTW imagery toward the interior surface of the lens.

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 method of designing lenses includes defining a material having an inside reflective surface spanning an area, and providing an optical design algorithm which defines a plurality of oxels across the area. Each oxel has a plurality of sub-elements including a center sub-element and a plurality of neighboring sub-elements. Based on a defined optical prescription for the inside reflective surface, an optically corrected reference 3D surface is calculated for each oxel having spherical and cylindrical corrections relative to a spherical contour which spans a predetermined field of view (FOV) with respect to a single (common) predetermined reference point. A position of at least a first of the sub-elements for each of the oxels is moved to respective final 3D positions on the optically corrected reference 3D surface, where the moving is constrained to be along an individual line connecting each of the first sub-elements to the single predetermined reference point.

Abstract: A system including a structure attachable to a surface in a real world environment, the structure establishing a known location and orientation of the structure, a docking element, as part of the structure, to secure an augmented reality device in a stationary position for alignment of the augmented reality device with the real world environment and with a parallel virtual environment, and a processor operable to perform the alignment by resetting the inertial navigation system of the augmented reality device to the known location when docked in the docking element and aligning the location and orientation of the virtual representation of the augmented reality device in the parallel virtual environment so that the parallel virtual environment in the augmented reality device overlaps the real world environment. A method and computer software produce are also disclosed.

Abstract: A system, method, and computer-readable instructions for a distributed machine learning system are provided. A plurality of distributed learning environments are in communication over a network, wherein each environment has a computing device having a memory and a processor coupled to the memory, the processor adapted implement a learning environment via one or more agents in a rules-based system, wherein the agents learn to perform tasks in their respective learning environment; and a persistent storage in which knowledge comprising a plurality of rules developed by the agents for performing the tasks are stored, wherein the knowledge is tagged and shared with other agents throughout the plurality of distributed learning environments.

Abstract: Systems and methods for capturing user engagements with Ad content included in a webpage. An example method renders a webpage having an Ad unit within a browser on a display of a user's computer. Then, a cursor event for an Ad unit included in the rendered webpage is recorded based on cursor position relative to an area on the webpage associated with the Ad unit and the recorded cursor event is transmitted to a server via a network for reporting to interested parties. The cursor event includes an initial cursor entry event, any click actions or any hover actions, and all related timings of such events. The recordation of a cursor event is further based on location information associated with the browser within the display, the webpage within the browser and the ad area within the webpage.

Abstract: Embodiments are directed to a mobile application that enables a completely and dynamically configurable workflow. Once installed on a mobile computer, the application is completely configurable without re-compiling the application. A user may configure the “look & feel,” as well as the workflow of a particular instance of the application, via configuration templates. Once the application is downloaded and installed in an executable form, the user may configure and/or reconfigure the workflow and the “look and feel” of the application without a re-compiling operation and/or generating new machine-code to enable the configuration. To configure and/or reconfigure the application, the user need only to edit and/or receive additional configuration templates. The execution of the configured workflow is not dependent upon the mobile computer being in communication with another network computer. The mobile application may be a native application.

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.