Methods and apparatus to stabilize and recover unmanned aerial vehicles (UAVs) are disclosed. A disclosed example apparatus includes a capture line, a mast to support the capture line for contact with the UAV, and a braking stabilizer. The braking stabilizer includes a flexible stem, a body at a distal end of the stem, where the body defines first and second flexible posts, and a filament extending between the first and second posts to contact and engage a hook of the UAV.

Capture devices for unmanned aerial vehicles, including track borne capture lines, and associated systems and methods are disclosed. An example system includes a support having an upright portion and a boom portion. The example system further includes a capture line carried by and extending downwardly relative to the boom portion. The capture line has an engagement portion positioned to engage an unmanned aircraft. The example system further includes a flexible landing device positioned to receive the unmanned aircraft in response to the unmanned aircraft engaging the engagement portion.

Systems and methods for recovering unmanned aircraft and controlling post-recovery motion of the aircraft are disclosed herein. An aircraft recovery system for handling an unmanned aircraft in accordance with one embodiment of the disclosure includes a base portion and an elongated aircraft capture member having a first end movably coupled to the base portion and a second, free end opposite the first end. The aircraft capture member includes a first portion and a second portion at a distal end of the first portion and positioned to intercept an unmanned aircraft in flight. The first and/or second portions are generally flexible. The system further includes an energy capture and dissipation assembly operably coupled to the aircraft capture member and positioned to receive at least a portion of the landing forces from the aircraft.

A position setting system including a first side plate, a second side plate and a bottom plate with two sides parallel to a length direction, each of the two sides abutting a respective side plate. The position setting system also has a first positioning device and a second positioning device configured to move along at least one of the two sides of the bottom plate, towards each other to guide and position a landing gear of the UAV to be between the first positioning device and the second positioning device during landing. During take-off, the first positioning device and the second positioning device are moved away from each other.

One variation of a tram system includes: a chassis; a latch configured to selectively engage a latch receiver mounted to an aircraft; an alignment feature adjacent the latch and configured to engage an alignment receiver mounted to the aircraft and to communicate acceleration and braking forces from the chassis into the aircraft; an optical sensor facing upwardly from the chassis; a drivetrain configured to accelerate and decelerate the chassis along a runway; and a controller configured to detect an optical fiducial arranged on the aircraft in optical images recorded by the optical sensor adjust a speed of the drivetrain to longitudinally align the alignment feature with the alignment receiver based on positions of the optical fiducial detected in the optical images, trigger the latch to engage the latch receiver once the aircraft has descended onto the chassis, and trigger the drivetrain to actively decelerate the chassis during a landing routine.

A generally vertical rocket (2) flies generally horizontally into recovery line, cable or chain (3) suspended between towers (5, 7) of a catamaran landing ship (9). High speed winches (11, 13), preferably located near or at the tops of the towers (5, 7) can rapidly reel in or out the recovery line (3) to effectively raise or lower the recovery line (3). The fixture engages a capture device on the rocket located usually above the rocket center of gravity. This invention provides a more reliable means of landing a rocket and also eliminates rocket weight, cost and complexity associated with previous means of landing a rocket.

Apparatus and methods for controlling an aircraft and/or a vehicle are described. A vehicle speed and direction are received. A wind-over-vehicle speed and direction of wind at the vehicle are measured. An aircraft ground speed and direction are received. An aircraft-relative-to-vehicle speed and an aircraft-relative-to-vehicle direction are calculated based on the aircraft ground speed and direction and the wind-over-vehicle speed and direction. A wind-over-vehicle envelope is calculated based on system design limits for retrieving the aircraft at the vehicle. The wind-over-vehicle envelope maps limits of wind-over-vehicle speeds over a range of directions that enable retrieval of the aircraft at the vehicle. The aircraft and/or the vehicle are controlled using the wind-over-vehicle envelope, the aircraft-relative-to-vehicle speed, and/or the aircraft-relative-to-vehicle direction.

Unmanned aerial vehicle (UAV) recovery is disclosed. An example apparatus to recover an unmanned aerial vehicle (UAV) includes a support rail to support a cable. The apparatus also includes a pivot arm to rotate about a pivot, where the cable is suspended between the support rail and the pivot arm, and where the pivot arm is rotated to a first orientation when the UAV contacts the cable and rotated to a second orientation when the UAV is brought to a stop. The apparatus also includes at least one of a friction device or a damper operatively coupled to the cable to resist motion of the cable during rotation of the pivot arm from the first orientation to the second orientation.

An apparatus and system for launching and/or capturing an unmanned aerial vehicle (UAV). The apparatus includes a moving substrate having an electromagnetic end effector and a UAV with a metallic strike plate to be attracted to the end effector when the electromagnet is activated. The system includes a movable robotic arm having a free end and a secured end; an electromagnetic end effector connected proximate to the free end of the robotic arm; a UAV with a metallic strike to be attracted and held to the electromagnetic end effector when the electromagnetic end effector is active; trajectory software configured to control a location of the free end of the robotic arm; and a control module for receiving input data, analyzing the data and using the trajectory software to control the location of and activate or deactivate the electromagnetic end effector. Also described are methods for launching and capturing the UAV.

A deck landing system for aircrafts, in particular rotating wing aircrafts, apt to implement a hook between the aircraft and the deck of a ship or of a floating platform, the deck being equipped with a target grid plate, it does not require the use of hydraulic systems and it comprises: a telescopic actuator (1) with a harpoon (3) having, at its own distal end, hooking grippers (7); and a control unit (9) which actuates said telescopic actuator (1), wherein the telescopic actuator (1) comprises a linear electromechanical actuator (8) having: a main battery (13) fed through a unit (12) for converting and conditioning the energy and connected to said telescopic actuator (1); and a device (10) for recovering and releasing the kinetic energy generated by the waves with the aircraft locked on said deck, is of the type acting with super-capacitors, which feeds said main battery (13).