Abstract: A system for creating and/or dynamically updating indoor positioning maps includes an augmented reality (AR) device and a computing device communicatively coupled to the AR device. The AR device has a display for displaying AR content to a user that overlaps the AR device's perspective view of an environment. The AR device also has one or more depth sensors for gathering mapping data of physical objects in the environment. The computing device has a processor that is configured by software to create a three-dimensional (3D) indoor positioning map of the environment in a building based on the mapping data gathered by the AR device, and/or dynamically update the 3D indoor positioning map of the environment in the building based on the mapping data gathered by the AR device.

Abstract: An augmented reality (AR) system, device, and method for reducing energy usage by monitoring and determining optimal control settings for conditions within a building. Sensors embedded in AR devices worn by workers performing job duties are utilized to detect and measure physical conditions such as visible light intensity and air temperature. Location, time/date, and worker occupancy data is also provided to the AR system. A time- and location-based data profile of environmental conditions within the building is created and regularly updated to track changes in environmental conditions over time. Algorithms running on a processor calculate and provide optimal control settings to building lighting and climate control systems. Optimal control settings take into account energy reduction goals, worker comfort, and regulatory compliance. The system utilizes the data profile to determine initial, reduced-energy control settings based on expected physical conditions within the building.

Abstract: A system for creating and/or dynamically updating indoor positioning maps includes an augmented reality (AR) device and a computing device communicatively coupled to the AR device. The AR device has a display for displaying AR content to a user that overlaps the AR device's perspective view of an environment. The AR device also has one or more depth sensors for gathering mapping data of physical objects in the environment. The computing device has a processor that is configured by software to create a three-dimensional (3D) indoor positioning map of the environment in a building based on the mapping data gathered by the AR device, and/or dynamically update the 3D indoor positioning map of the environment in the building based on the mapping data gathered by the AR device.

Abstract: An augmented reality (AR) system, device, and method for reducing energy usage by monitoring and determining optimal control settings for conditions within a building. Sensors embedded in AR devices worn by workers performing job duties are utilized to detect and measure physical conditions such as visible light intensity and air temperature. Location, time/date, and worker occupancy data is also provided to the AR system. A time- and location-based data profile of environmental conditions within the building is created and regularly updated to track changes in environmental conditions over time. Algorithms running on a processor calculate and provide optimal control settings to building lighting and climate control systems. Optimal control settings take into account energy reduction goals, worker comfort, and regulatory compliance. The system utilizes the data profile to determine initial, reduced-energy control settings based on expected physical conditions within the building.

Abstract: A remote transit authority fare collection system includes at least one server configured to receive fare collection information and at least one database configured to store the fare collection information received by the at least one server. The at least one server is further configured to aggregate the fare collection information, and the at least one server is further configured to analyze the fare collection information, wherein the fare collection information received by the at least one server is received over a network from a remote unit. The invention further includes a remote transit authority fare collection process.

Abstract: An improved wafer surface inspection system is disclosed. In one embodiment, the object surface inspection system includes a translation stage that generates relative motion between an object viewing device such as an objective lens and the surface of the object being inspected. A translation stage controller controls the relative movement of the object surface and the object viewing device. The translation stage controller determines current coordinates for the object surface and the object viewing device, compares the current coordinates to target coordinates generated by a processor, and generates a trigger signal in response to a match between the current coordinates to the target coordinates. A camera receives an image through the object viewing device and captures the image in response to the trigger signal while the translation stage generates relative motion between the object surface and the object viewing device.

Abstract: A compact hand-held viewing apparatus that automatically determines the three-dimensional direction in which it is pointing and automatically presents information to the user related to features which are visible in the field of view of the apparatus in that three-dimensional direction. Any given embodiment of the invention is intended to be used for viewing a predetermined subject matter, such as astronomical features of the night sky or geographical features of the distant terrain. Included within the apparatus is a database with data about the predetermined subject matter correlated with three-dimensional direction. The apparatus is configured to provide data from the database in real time to the user as the user observes the field of view in a selected three-dimensional direction.

Abstract: A system and method for optically measuring parameters such as dry basis weight of fibrous sheet materials during manufacture without scanning. The system includes mirror sections for reflecting modulated light as parallel rays perpendicularly incident upon one surface of a traveling web, and a plurality of light detection devices to detect light transmitted through the web at two distinct wavelengths. The system further includes ducts to environmentally isolate the mirror sections and the light detection devices.