An aerial vehicle for delivering a package. The aerial vehicle having a package deployment system coupled to the aerial vehicle. The package deployment system having a spool coupled to the aerial vehicle, a lowering line fixedly coupled to the spool at a first end, the lowering line having a second end secured to a grasping device, and a cutting device coupled to one of the spool or the lowering line. The aerial vehicle also having a package coupled to the grasping device and a monitoring system couple to one of the aerial vehicle or the package deployment system. The package deployment system is configured to deliver the package at a delivery location. The cutting device is configured to sever the lowering line to deliver the package. A method for delivering a package with an aerial vehicle having the package deployment system.

The invention relates to an assembly (10) comprising a launch motor vehicle (12) and a drone (14), the launch motor vehicle (12) being capable of travelling on a launch track to exceed a given speed threshold relative to a surrounding air mass, the launch motor vehicle (12) being provided with a launch ramp (20) cooperating with the drone (14) to, in a launching position, guide the drone (14) from a starting position in a launch direction to the front of the launch motor vehicle (12). The drone (14) comprises one or more reactors (30) and does not comprise a landing gear.

Aspects of modular airborne delivery are described. When a shipping container is provided to an airborne carrier for delivery, the airborne carrier may assess weather across a route for airborne delivery of the shipping container, evaluate an approach to drop the shipping container at a delivery zone, and calculate a remaining amount of time until a target delivery time, for example. The airborne carrier may then select components to assemble a modular unmanned aerial vehicle (UAV) based on those or other factors, and assemble the UAV using the selected components. The modular UAV may then be directed to deliver the shipping container according to instructions from the airborne carrier. According to the concepts described herein, flexibility and other advantages may be achieved using modular UAVs for airborne delivery.

A catch net for receiving a package from an aerial vehicle. The catch net has a net, the net configured to receive the package from the aerial vehicle. The catch net has a structure configured to support the net. The catch net has a module operably coupled to at least one of the net or the structure. The catch net is configured to move between a first position where the catch net is stored and a second position where the catch net is deployed for receiving a package. The catch net is configured to move between the first position and the second position via a signal sent to the module from at least one of the aerial vehicle or a consumer mobile device.

A payload retrieval system including a UAV having a payload receptacle positioned within the UAV, a payload coupling apparatus positioned within the payload receptacle, a tether having a first end secured within the UAV and a second end attached to the payload coupling apparatus, and a payload guiding member positioned on an underside of the UAV for guiding at least part of a payload into the payload receptacle during retrieval of a payload.

Example implementations may relate to using an unmanned aerial vehicle (UAV) dedicated to deployment of operational infrastructure, with such deployment enabling charging of a battery of a UAV from a group of UAVs. More specifically, the group of UAVs may include at least (i) a first UAV of a first type configured to deploy operational infrastructure and (ii) a second UAV of a second type configured to carry out a task other than deployment of operational infrastructure. With this arrangement, a control system may determine an operational location at which to deploy operational infrastructure, and may cause the first UAV to deploy operational infrastructure at the operational location. Then, the control system may cause the second UAV to charge a battery of the second UAV using the operational infrastructure deployed by the first UAV at the operational location.

Described herein is a control system that facilitates assistance mode(s). In particular, the control system may determine a particular assistance mode associated with an account. This particular assistance mode may specify (i) operations for an aerial vehicle to carry out in order to obtain sensor data providing environment information corresponding to a location associated with the account and (ii) feedback processes to provide feedback, via a feedback system associated with the account, that corresponds to respective environment information. The control system may transmit to the aerial vehicle an indication of the particular operations corresponding to the particular assistance mode and may then receive environment information for the location associated with the account. Based on the received environment information, the control system may apply the specified feedback processes to initiate feedback in accordance with the particular assistance mode via the associated feedback system.

A tiltrotor aircraft has a vertical takeoff and landing flight mode and a forward flight mode. The aircraft includes an airframe having a wing with oppositely disposed wing tips. Tip booms respectively extend longitudinally from the wing tips. Forward rotors are coupled to the forward ends of the tip booms and aft rotors are coupled to the aft ends of the tip booms. The forward rotors are reversibly tiltable between a vertical lift orientation, wherein the forward rotors are above the tip booms, and a forward thrust orientation, wherein the forward rotors are forward of the tip booms. The aft rotors are reversibly tiltable between a vertical lift orientation, wherein the aft rotors are below the tip booms, and a forward thrust orientation, wherein the aft rotors are aft of the tip booms. One of a plurality of payload modules is interchangeable coupled to the airframe, wherein each payload module has a respective function.

A method according to certain embodiments generally involves operating a system including an unmanned aerial vehicle (UAV) and a base station. The base station includes a nest including an upper opening having an upper opening diameter and a lower opening having a lower opening diameter less than the upper opening diameter. The lower opening is accessible from within the base station. The method generally includes landing the UAV within the nest such that a portion of the UAV is accessible via the lower opening, releasably attaching a load to the UAV, and operating the UAV to deliver the load to a destination.

An unmanned aerial vehicle according to certain embodiments generally includes a chassis, a control system, and at least one rotor. The chassis includes a first battery compartment configured to receive sliding insertion of a first battery, and a second battery compartment configured to receive sliding insertion of a second battery. The control system is operable to receive power from the first battery and the second battery when the first battery is received in the first battery compartment and the second battery is received in the second battery compartment. The at least one rotor is operable to generate lift under control of the control system when both the first battery and the second battery are installed to the chassis. The control system is configured to remain at least partially active under power supplied by the first battery when the second battery is removed from the second battery compartment.