An unmanned aerial vehicle may include a fuselage and an anchor structure coupled to the fuselage and including a wing retention structure and a power module retention structure. The unmanned aerial vehicle may also include a wing releasably coupled to the wing retention structure, thereby coupling the wing to the fuselage, and a power module releasably coupled to the power module retention structure, thereby coupling the power module to the fuselage.

An aerial vehicle includes at least one wing, a plurality of thrust producing elements on the at least one wing, a plurality of electric motors equal to the number of thrust producing elements for individually driving each of the thrust producing elements, at least one battery for providing power to the motors, and a flight control system to control the operation of the vehicle. The aerial vehicle may include a fuselage configuration to facilitate takeoffs and landings in horizontal, vertical and transient orientations, redundant control and thrust elements to improve reliability and means of controlling the orientation stability of the vehicle in low power and multiple loss of propulsion system situations. Method of flying an aerial vehicle includes the variation of the rotational speed of the thrust producing elements to achieve active vehicle control.

An aerial vehicle includes at least one wing, a plurality of thrust producing elements on the at least one wing, a plurality of electric motors equal to the number of thrust producing elements for individually driving each of the thrust producing elements, at least one battery for providing power to the motors, and a flight control system to control the operation of the vehicle. The aerial vehicle may include a fuselage configuration to facilitate takeoffs and landings in horizontal, vertical and transient orientations, redundant control and thrust elements to improve reliability and means of controlling the orientation stability of the vehicle in low power and multiple loss of propulsion system situations. Method of flying an aerial vehicle includes the variation of the rotational speed of the thrust producing elements to achieve active vehicle control.

A method for deploying a payload into a body of water using a deployment vessel, the deployment vessel including a hull defining a payload compartment, the method including positioning the payload in the payload compartment of the deployment vessel, the deployment vessel and the payload having a buoyancy, wherein the buoyancy is initially negative, deploying the deployment vessel into the water at a drop zone, wherein the deployment vessel moves horizontally through the water as it submerges vertically downward under a force of gravity, changing the buoyancy to positive after a minimum horizontal distance is established between the drop zone and the deployment vessel, thereby causing the deployment vessel to surface and, after the surfacing of the deployment vessel, opening the hull to release the payload therefrom.

A method for deploying a payload into a body of water using a deployment vessel, the deployment vessel including a hull defining a payload compartment, the method including positioning the payload in the payload compartment of the deployment vessel, the deployment vessel and the payload having a buoyancy, wherein the buoyancy is initially negative, deploying the deployment vessel into the water at a drop zone, wherein the deployment vessel moves horizontally through the water as it submerges vertically downward under a force of gravity, changing the buoyancy to positive after a minimum horizontal distance is established between the drop zone and the deployment vessel, thereby causing the deployment vessel to surface and, after the surfacing of the deployment vessel, opening the hull to release the payload therefrom.

An image capturing system for shape measurement includes: an image capturing device configured to capture an image of a structure; an air vehicle; an on-board control device configured to control the image capturing device and the air vehicle in accordance with an image capturing scenario; and a remote control device configured to create an image capturing scenario and transfer the created image capturing scenario to the on-board control device. The air vehicle autonomously flies to image capturing points sequentially so as to capture images. The captured data is transmitted to the remote control device via a wireless LAN.

An image capturing system for shape measurement includes: an image capturing device configured to capture an image of a structure; an air vehicle; an on-board control device configured to control the image capturing device and the air vehicle in accordance with an image capturing scenario; and a remote control device configured to create an image capturing scenario and transfer the created image capturing scenario to the on-board control device. The air vehicle autonomously flies to image capturing points sequentially so as to capture images. The captured data is transmitted to the remote control device via a wireless LAN.

An emergency beacon is configured to replace of one or more navigation lamps installed on an aircraft, which has a fuselage with an outer face, on which is fixed a second interface, on which such a navigation lamp is typically disposed; the emergency beacon includes a base, which has a first interface configured to cooperate with the second interface of the aircraft to fix the base onto the outer face of the fuselage; a casing with a control unit, a radio transmitter for transmitting a distress signal, and a detector to detect abnormal aircraft behavior; and a fixing structure to take up a fixation position, ensuring the casing is fixed to the base, or a separation position, in which it does not ensure the casing is fixed to the base; the transition from fixation position to separation position is controlled by the control unit when an abnormal behavior is detected.

An emergency beacon is configured to replace of one or more navigation lamps installed on an aircraft, which has a fuselage with an outer face, on which is fixed a second interface, on which such a navigation lamp is typically disposed; the emergency beacon includes a base, which has a first interface configured to cooperate with the second interface of the aircraft to fix the base onto the outer face of the fuselage; a casing with a control unit, a radio transmitter for transmitting a distress signal, and a detector to detect abnormal aircraft behavior; and a fixing structure to take up a fixation position, ensuring the casing is fixed to the base, or a separation position, in which it does not ensure the casing is fixed to the base; the transition from fixation position to separation position is controlled by the control unit when an abnormal behavior is detected.

A method for extracting a rescue subject from a surface position includes lowering a rescue pod having an enclosed compartment with a door from an aircraft, the rescue pod having a parachute and a control system, the rescue pod connected by a tether to a winch in the aircraft, controllably releasing the tether from the winch while maneuvering the aircraft into an orbit at altitude, diameter and airspeed, creating a gravity well in which the tether describes a spiral configuration with the pod descending along a vertical centerline, lowering the pod to the surface position, loading the rescue subject into the enclosed compartment, and lifting the rescue pod from the surface position by retrieving the tether with the winch or altering the path and speed of the aircraft, in a manner to gradually increase tension in the tether lifting the rescue pod from the ground point.