Abstract: Disclosed are devices, systems and methods for mission-adaptable aerial vehicle. In some aspects, a mission-adaptable aerial vehicle includes a configuration having swappable, manipulatable, and interchangeable sections and components connectable by a connection and fastening system able to be modified by an end-user in the field. In some embodiments, a mission-adaptable aerial vehicle can be configured to include a main center body extending along a longitudinal direction, a wing with a lateral cross-sectional airfoil shape, and/or stabilizer and control surface structures with corresponding cross-sectional airfoil shapes.

Abstract: Disclosed are devices, systems and methods for mission-adaptable aerial vehicle. In some aspects, a mission-adaptable aerial vehicle includes a configuration having swappable, manipulatable, and interchangeable sections and components connectable by a connection and fastening system able to be modified by an end-user in the field. In some embodiments, a mission-adaptable aerial vehicle can be configured to include a main center body extending along a longitudinal direction, a wing with a lateral cross-sectional airfoil shape, and/or stabilizer and control surface structures with corresponding cross-sectional airfoil shapes.

Abstract: Disclosed are devices, systems and methods for mission-adaptable aerial vehicle. In some aspects, a mission-adaptable aerial vehicle includes a configuration having swappable, manipulatable, and interchangeable sections and components connectable by a connection and fastening system able to be modified by an end-user in the field. In some embodiments, a mission-adaptable aerial vehicle can be configured to include a main center body extending along a longitudinal direction, a wing with a lateral cross-sectional airfoil shape, and/or stabilizer and control surface structures with corresponding cross-sectional airfoil shapes.

Abstract: Disclosed are devices, systems and methods for mission-adaptable aerial vehicle. In some aspects, a mission-adaptable aerial vehicle includes a configuration having swappable, manipulatable, and interchangeable sections and components connectable by a connection and fastening system able to be modified by an end-user in the field. In some embodiments, a mission-adaptable aerial vehicle can be configured to include a main center body extending along a longitudinal direction, a wing with a lateral cross-sectional airfoil shape, and/or stabilizer and control surface structures with corresponding cross-sectional airfoil shapes.

Abstract: Disclosed are devices, systems and methods for mission-adaptable aerial vehicle. In some aspects, a mission-adaptable aerial vehicle includes a configuration having swappable, manipulatable, and interchangeable sections and components connectable by a connection and fastening system able to be modified by an end-user in the field. In some embodiments, a mission-adaptable aerial vehicle can be configured to include a main center body extending along a longitudinal direction, a wing with a lateral cross-sectional airfoil shape, and/or stabilizer and control surface structures with corresponding cross-sectional airfoil shapes.

Abstract: Disclosed are devices, systems and methods for mission-adaptable aerial vehicle. In some aspects, a mission-adaptable aerial vehicle includes a configuration having swappable, manipulatable, and interchangeable sections and components connectable by a connection and fastening system able to be modified by an end-user in the field. In some embodiments, a mission-adaptable aerial vehicle can be configured to include a main center body extending along a longitudinal direction, a wing with a lateral cross-sectional airfoil shape, and/or stabilizer and control surface structures with corresponding cross-sectional airfoil shapes.

Abstract: Disclosed are devices, systems and methods for mission-adaptable aerial vehicle. In some aspects, a mission-adaptable aerial vehicle includes a configuration having swappable, manipulatable, and interchangeable sections and components connectable by a connection and fastening system able to be modified by an end-user in the field. In some embodiments, a mission-adaptable aerial vehicle can be configured to include a main center body extending along a longitudinal direction, a wing with a lateral cross-sectional airfoil shape, and/or stabilizer and control surface structures with corresponding cross-sectional airfoil shapes.

Abstract: Disclosed are devices, systems and methods for mission-adaptable aerial vehicle. In some aspects, a mission-adaptable aerial vehicle includes a configuration having swappable, manipulatable, and interchangeable sections and components connectable by a connection and fastening system able to be modified by an end-user in the field. In some embodiments, a mission-adaptable aerial vehicle can be configured to include a main center body extending along a longitudinal direction, a wing with a lateral cross-sectional airfoil shape, and/or stabilizer and control surface structures with corresponding cross-sectional airfoil shapes.

Abstract: Methods, systems, and devices are disclosed for image acquisition and distribution of individuals at large events. In one aspect, a method for providing an image of attendees at an event includes operating one or more image capturing devices to record images of attendees of an event situated at locations in an event venue, processing the images to form a processed image, and distributing the processed image to the individual. The processing includes mapping the locations to a grid including coordinates corresponding to predetermined positions associated with the event venue, defining an image space containing an individual at a particular location in the event venue based on the coordinates, and forming the processed image based on the image space.

Abstract: Methods, systems, and devices are disclosed for image acquisition and distribution of individuals at large events. In one aspect, a method for providing an image of attendees at an event includes operating one or more image capturing devices to record images of attendees of an event situated at locations in an event venue, processing the images to form a processed image, and distributing the processed image to the individual. The processing includes mapping the locations to a grid including coordinates corresponding to predetermined positions associated with the event venue, defining an image space containing an individual at a particular location in the event venue based on the coordinates, and forming the processed image based on the image space.

Abstract: Systems, devices and methods are disclosed for detecting, characterizing and engaging unmanned vehicles. In one aspect, a method includes detecting an object, such as an unmanned aerial, land or aquatic vehicle that communicates using a radio control (RC) communications protocol, traveling to a zone including scanning one or more frequencies of RF signals; analyzing one or both of time and frequency information of the RF signals to characterize the detected object; and engaging the detected object as an authorized or unauthorized object in the monitored zone.

Abstract: Methods, systems, and devices are disclosed for image acquisition and distribution of individuals at large events. In one aspect, a method for providing an image of attendees at an event includes operating one or more image capturing devices to record images of attendees of an event situated at locations in an event venue, processing the images to form a processed image, and distributing the processed image to the individual. The processing includes mapping the locations to a grid including coordinates corresponding to predetermined positions associated with the event venue, defining an image space containing an individual at a particular location in the event venue based on the coordinates, and forming the processed image based on the image space.

Abstract: Methods, systems, and devices are disclosed for image acquisition and distribution of individuals at large events. In one aspect, a method for providing an image of attendees at an event includes operating one or more image capturing devices to record images of attendees of an event situated at locations in an event venue, processing the images to form a processed image, and distributing the processed image to the individual. The processing includes mapping the locations to a grid including coordinates corresponding to predetermined positions associated with the event venue, defining an image space containing an individual at a particular location in the event venue based on the coordinates, and forming the processed image based on the image space.