The present disclosure provides an aircraft comprising: a fuselage; and a payload module coupled to the fuselage, the payload module comprising one or more data storage devices. The payload module is configured to be decoupled from the fuselage during flight upon receipt of a de-coupling input.

The present disclosure provides an aircraft comprising: a fuselage; and a payload module coupled to the fuselage, the payload module comprising one or more data storage devices. The payload module is configured to be decoupled from the fuselage during flight upon receipt of a de-coupling input.

An unmanned aerial vehicle, including: a propelling device configured to generate a downward airstream; a package carrier; and wheels arranged so as to allow the package carrier to stand alone. The package carrier includes: vertical members which surround a package in a horizontal direction to prevent falling of the package; support members configured to support a load of the package at positions; and a coupling device configured to hold vertical members so as to enable relative horizontal movement. The support members are each fixed to a corresponding one of the vertical members. The wheels are each mounted to the corresponding one of the vertical members, and enable the relative horizontal movement of the vertical members under a state in which the wheels are on the ground. Through the relative horizontal movement of the vertical members, the package is separable from the support members.

Methods of reducing wing type parachute opening shock during a parachute drop, and parachute systems with reduced opening shocks are disclosed, the opening force reduction is achieved by dynamic braking, i.e. dynamically adjusting the canopy control lines during the inflation stage of the canopy. Typically, the control lines are set to zero brake length when the parachute canopy is released from the deployment bag, and are at least shortened during the inflation stage, optionally all the way to full brake. Optionally the control lines are also lengthened prior to completion of the canopy inflation. Other features and parachute systems are also disclosed.

A storage and release mechanism for aerial distribution and release of insects from an unmanned aerial vehicle, the release being aimed at controlling a wild insect population, the wild population having fluctuating local densities, the mechanism comprising a switch for switching between two or more different sustainable insect delivery rates for release of the insects. The method is particularly suitable for sterile male mosquitoes in programs to control wild mosquito populations.

A storage and release mechanism for aerial distribution and release of insects from an unmanned aerial vehicle, the release being aimed at controlling a wild insect population, the wild population having fluctuating local densities, the mechanism comprising a switch for switching between two or more different sustainable insect delivery rates for release of the insects. The method is particularly suitable for sterile male mosquitoes in programs to control wild mosquito populations.

A capture system (1) includes a drone (4) with a capture device (3) having a net (5) and a shank (6) configured to form a closed line. The shank (6) defines a leading face (6A) and a trailing face (6B). The net (5) has a maximum diameter that is greater than a maximum diameter of the shank (6), and is attached to the shank (6) on the side (7) of the trailing face (6B). A strip (8) attaches completely around the shank (6) outside of the net (5) on the side (7) of the trailing face (6B). Holding wires (9) attach to the shank (6) on the side (10) of the leading face (6A) for towing by the drone (4). The assembly formed by the shank (6) and the strip (8) enabling the capture device (3) to be held in an optimum position for capturing a flying craft (2).

A capture system (1) includes a drone (4) with a capture device (3) having a net (5) and a shank (6) configured to form a closed line. The shank (6) defines a leading face (6A) and a trailing face (6B). The net (5) has a maximum diameter that is greater than a maximum diameter of the shank (6), and is attached to the shank (6) on the side (7) of the trailing face (6B). A strip (8) attaches completely around the shank (6) outside of the net (5) on the side (7) of the trailing face (6B). Holding wires (9) attach to the shank (6) on the side (10) of the leading face (6A) for towing by the drone (4). The assembly formed by the shank (6) and the strip (8) enabling the capture device (3) to be held in an optimum position for capturing a flying craft (2).

A payload release device, a payload release assembly including a payload release device, and methods for arming a payload release device. A payload release device includes a member and a button. The member has a top portion, a bottom portion, and a middle portion. The middle portion has an aperture defining a bottom edge, a first upwardly sloping edge, and a second upwardly sloping edge, wherein each upwardly sloping edge is upwardly sloping with respect to the bottom edge. The button has a top surface and is at least partially disposed in the aperture, wherein the button is depressed toward the first upwardly sloping edge when force is applied thereto, wherein the button raises toward the second upwardly sloping edge when at least a portion of the force applied to the button is released, and wherein the second upwardly sloping edge is parallel with the top surface of the button.

A payload release device, a payload release assembly including a payload release device, and methods for arming a payload release device. A payload release device includes a member and a button. The member has a top portion, a bottom portion, and a middle portion. The middle portion has an aperture defining a bottom edge, a first upwardly sloping edge, and a second upwardly sloping edge, wherein each upwardly sloping edge is upwardly sloping with respect to the bottom edge. The button has a top surface and is at least partially disposed in the aperture, wherein the button is depressed toward the first upwardly sloping edge when force is applied thereto, wherein the button raises toward the second upwardly sloping edge when at least a portion of the force applied to the button is released, and wherein the second upwardly sloping edge is parallel with the top surface of the button.