The present disclosure provides a system for intercepting a rogue drone, the system comprising: a broad-angle electromagnetic radiation emitter for illuminating a cone of sky with coded electromagnetic radiation; and an air vehicle. The air vehicle comprises: an electromagnetic radiation detector for receiving coded electromagnetic radiation reflected from a rogue drone operating in the cone of sky, the detector comprising a notch filter for selecting the coded electromagnetic radiation and for disregarding light from other sources; and a controller for determining the position of the rogue drone based on the received coded electromagnetic radiation. The present invention also provides an air vehicle for intercepting a rogue drone and a method of intercepting a rogue drone.

The present disclosure provides a system for intercepting a rogue drone, the system comprising: a broad-angle electromagnetic radiation emitter for illuminating a cone of sky with coded electromagnetic radiation; and an air vehicle. The air vehicle comprises: an electromagnetic radiation detector for receiving coded electromagnetic radiation reflected from a rogue drone operating in the cone of sky, the detector comprising a notch filter for selecting the coded electromagnetic radiation and for disregarding light from other sources; and a controller for determining the position of the rogue drone based on the received coded electromagnetic radiation. The present invention also provides an air vehicle for intercepting a rogue drone and a method of intercepting a rogue drone.

Recently, jobs involving transporting goods, tasks involving surveying a wide area, etc. using multicopters have increased, and it has become necessary for multicopters to fly for long periods of time, In the present invention, wings that are separate from the main body are provided all the way around or at individual locations around it to connect neighboring pairs of the multiple arms extending radially from it, in order to increase the multicopter’s lift and extend its flight time.

Recently, jobs involving transporting goods, tasks involving surveying a wide area, etc. using multicopters have increased, and it has become necessary for multicopters to fly for long periods of time, In the present invention, wings that are separate from the main body are provided all the way around or at individual locations around it to connect neighboring pairs of the multiple arms extending radially from it, in order to increase the multicopter’s lift and extend its flight time.

The present disclosure is directed toward a system for autonomously landing an unmanned aerial vehicle (UAV) within an unmanned aerial vehicle ground station (UAVGS) and removing a battery assembly from within the UAV while landed. In particular, systems described herein enable a battery arm to engage a battery assembly and remove the battery assembly from within the UAV. Additionally, the battery arm can include one or more sensors that detect a pattern of sensor contacts arranged on an end of the battery assembly. In particular, the sensors on the battery arm can detect and identify the battery assembly based on the particular pattern of sensor contacts on the end of the battery assembly.

A vertical tail of a composite-wing unmanned aerial vehicle (UAV) having a body, a rudder face section, a rotor section, shock absorbing component and a quick installation assembly of circuit. The body includes a tail body frame and a shell. The rudder face section has a rudder machine and a rudder surface. The rudder surface is connected to one end of the tail for steering the directional deflection of the UAV. The shock absorbing component is connected to the lower end plate and the shock absorbing component absorbs the shock to the body. The quick installation assembly of circuit includes a plug, a positioning sleeve and a bias piece, the positioning sleeve is located on the outer circumference of the plug and slidingly connected to the plug, the bias piece is set between the plug and the positioning sleeve, the bias piece can absorb the impact on the plug.

A vertical tail of a composite-wing unmanned aerial vehicle (UAV) having a body, a rudder face section, a rotor section, shock absorbing component and a quick installation assembly of circuit. The body includes a tail body frame and a shell. The rudder face section has a rudder machine and a rudder surface. The rudder surface is connected to one end of the tail for steering the directional deflection of the UAV. The shock absorbing component is connected to the lower end plate and the shock absorbing component absorbs the shock to the body. The quick installation assembly of circuit includes a plug, a positioning sleeve and a bias piece, the positioning sleeve is located on the outer circumference of the plug and slidingly connected to the plug, the bias piece is set between the plug and the positioning sleeve, the bias piece can absorb the impact on the plug.

A UAV for transporting a payload comprising a vehicle body; a retractable rail exposed on an underside of the vehicle body; a retraction mechanism coupling the rail to the vehicle body for causing the rail to raise and lower relative to the vehicle body; and a barrier located on the vehicle body so as to confront the rail when the rail is in its raised position to block the removal from the rail of a payload slidably engaged with the rail. A mechanism for advancing a payload onto and along the rail and pushing it off.

FIG. 1

A UAV for transporting a payload comprising a vehicle body; a retractable rail exposed on an underside of the vehicle body; a retraction mechanism coupling the rail to the vehicle body for causing the rail to raise and lower relative to the vehicle body; and a barrier located on the vehicle body so as to confront the rail when the rail is in its raised position to block the removal from the rail of a payload slidably engaged with the rail. A mechanism for advancing a payload onto and along the rail and pushing it off.

FIG. 1

The present disclosure relates to a method of navigating an unmanned aerial vehicle (UAV). The method includes the steps of controlling a flight path of the UAV by a remote operator, obtaining a recognized air picture of an observation space surrounding the UAV, assigning one of a plurality of threat levels to each of the aerial vehicles, the threat levels comprising a resolution advisory level and an automatic avoidance level and continuously automatically determining viable avoidance trajectories for the UAV). If an aerial vehicles is assigned the resolution advisory level, a message is provided to a remote operator including a first proposed viable avoidance trajectory. If an aerial vehicles is assigned the automatic avoidance level, control signals are provided to an on-board flight controller instructing the vehicle to follow a flight path corresponding to a second proposed viable avoidance trajectory.