Abstract: A system includes a plurality of sensors along a surface of an airfoil operable to measure a first set of ice thickness values at a first time and a second set of ice thickness values at a second time. The system further includes a processor configured to determine a first plurality of lift calculation variables and a second plurality of lift calculation variables. The processor also generates a threshold angle of attack value and updates the threshold angle of attack value at the second time, based on one or more differences between the first and second sets of ice thickness values and the first and second plurality of lift calculation variables. The processor is further configured to send, to a display, based on the updated threshold angle of attack, one or more changes to flight data to adjust the actual angle of attack of the airfoil.

Abstract: A system includes a plurality of sensors along a surface of an airfoil operable to measure a first set of ice thickness values at a first time and a second set of ice thickness values at a second time. The system further includes a processor configured to determine a first plurality of lift calculation variables and a second plurality of lift calculation variables. The processor also generates a threshold angle of attack value and updates the threshold angle of attack value at the second time, based on one or more differences between the first and second sets of ice thickness values and the first and second plurality of lift calculation variables. The processor is further configured to send, to a display, based on the updated threshold angle of attack, one or more changes to flight data to adjust the actual angle of attack of the airfoil.

Abstract: A system includes an ultraviolet light source, a light-receiving apparatus, and a performance detector. The ultraviolet light source is configured to expose a surface to ultraviolet light. The surface includes a surface coating and a fluorescence layer beneath the surface coating. The light-receiving apparatus is configured to measure a fluorescence response to the ultraviolet light of the surface by detecting light in a predetermined frequency range within the visible light spectrum light. The performance detector is communicatively coupled to the light-receiving apparatus. The performance detector is configured to determine a proportion of the surface comprising the surface coating disposed over the fluorescence layer based on the measured fluorescence response. The performance detector is further configured to compare the determined proportion to a predetermined threshold.

Abstract: A method for determining the physical location of a vehicle being guided with an onboard navigational positioning system capable of detecting and generating a positioning location vector for the vehicle. The method includes the steps of detecting and receiving a plurality of electromagnetic radiation signals. A plurality of ambient parameter measurements is also received. A confirming location position is calculated from the plurality of electromagnetic radiation signals and the plurality of ambient parameter measurements. The confirming location position is compared to the positioning location vector generated by the onboard system to create a differential vector. If the confirmation location position and the positioning location vector are greater than a predetermined value, the positioning location vector generated by the onboard navigational positioning system is prevented from being used in directing the movement of the vehicle until the position differential is below a predetermined error value.

Abstract: A method for determining the physical location of a vehicle being guided with an onboard navigational positioning system capable of detecting and generating a positioning location vector for the vehicle. The method includes the steps of detecting and receiving a plurality of electromagnetic radiation signals. A plurality of ambient parameter measurements is also received. A confirming location position is calculated from the plurality of electromagnetic radiation signals and the plurality of ambient parameter measurements. The confirming location position is compared to the positioning location vector generated by the onboard system to create a differential vector. If the confirmation location position and the positioning location vector are greater than a predetermined value, the positioning location vector generated by the onboard navigational positioning system is prevented from being used in directing the movement of the vehicle until the position differential is below a predetermined error value.

Abstract: A metallic flake manufacturing device uses a bearing to form the flakes. The bearing is located within a container which receives a fluid having suspended metallic particles. The bearing has an outer race, an inner race, and a plurality of bearings disposed between the races. The bearings are immersed in the fluid for flattening the suspended particles into flakes. A shaft extends into the container. The shaft engages one of the races for rotating it relative to the other race.