An unmanned aerial vehicle assembly includes an unmanned aerial vehicle including a plurality of propulsion units thereby facilitating the unmanned aerial vehicle to fly. A plurality of cameras is each coupled to the unmanned aerial vehicle to capture imagery of the area surrounding the unmanned aerial vehicle. A microphone is coupled to the unmanned aerial vehicle to capture audible sounds in the area surrounding the unmanned aerial vehicle. A transceiver is integrated into the unmanned aerial vehicle and the transceiver is in communication with an extrinsic communication network. In this way the transceiver can receive flight control commands from a personal electronic device that is in communication with the extrinsic communication network thereby facilitating an authorized user to remotely control the unmanned aerial vehicle. A user interface is integrated into the unmanned aerial vehicle to capture a signature from a person. The user interface is in electrical communication with the transceiver thereby facilitating the signature to be communicated to the authorized user.

An unmanned aerial vehicle assembly includes an unmanned aerial vehicle including a plurality of propulsion units thereby facilitating the unmanned aerial vehicle to fly. A plurality of cameras is each coupled to the unmanned aerial vehicle to capture imagery of the area surrounding the unmanned aerial vehicle. A microphone is coupled to the unmanned aerial vehicle to capture audible sounds in the area surrounding the unmanned aerial vehicle. A transceiver is integrated into the unmanned aerial vehicle and the transceiver is in communication with an extrinsic communication network. In this way the transceiver can receive flight control commands from a personal electronic device that is in communication with the extrinsic communication network thereby facilitating an authorized user to remotely control the unmanned aerial vehicle. A user interface is integrated into the unmanned aerial vehicle to capture a signature from a person. The user interface is in electrical communication with the transceiver thereby facilitating the signature to be communicated to the authorized user.

A telescoping tail assembly for use on an aircraft that has a fore-aft length. The telescoping tail assembly includes a housing extending in an aftward direction and a tailboom slidable along the housing into various positions including an extended position and a retracted position. A jackscrew is coupled to the tailboom. An actuator is coupled to the jackscrew and is configured to selectively rotate the jackscrew to translate the tailboom between the plurality of positions. The tailboom has one or more control surfaces coupled thereto. The tailboom increases the fore-aft length of the aircraft in the extended position and decreases the fore-aft length of the aircraft in the retracted position.

A telescoping tail assembly for use on an aircraft that has a fore-aft length. The telescoping tail assembly includes a housing extending in an aftward direction and a tailboom slidable along the housing into various positions including an extended position and a retracted position. A jackscrew is coupled to the tailboom. An actuator is coupled to the jackscrew and is configured to selectively rotate the jackscrew to translate the tailboom between the plurality of positions. The tailboom has one or more control surfaces coupled thereto. The tailboom increases the fore-aft length of the aircraft in the extended position and decreases the fore-aft length of the aircraft in the retracted position.

Systems, devices, and methods for a ground support system for an unmanned aerial vehicle (UAV) including: at least one handling fixture, where each handling fixture is configured to support at least one wing panel of the UAV; and at least one dolly, where each dolly is configured to receive at least one landing pod of the UAV, and where each landing pod supports at least one wing panel of the UAV; where the at least one handling fixture and the at least one dolly are configured to move and rotate two or more wing panels to align the two or more wing panels with each other for assembly of the UAV; and where the at least one dolly further allows for transportation of the UAV over uneven terrain.

Systems, devices, and methods for a ground support system for an unmanned aerial vehicle (UAV) including: at least one handling fixture, where each handling fixture is configured to support at least one wing panel of the UAV; and at least one dolly, where each dolly is configured to receive at least one landing pod of the UAV, and where each landing pod supports at least one wing panel of the UAV; where the at least one handling fixture and the at least one dolly are configured to move and rotate two or more wing panels to align the two or more wing panels with each other for assembly of the UAV; and where the at least one dolly further allows for transportation of the UAV over uneven terrain.

A vertical take-off and landing (“VTOL”) aircraft has at least two flying wings (“FW”) with each FW equipped with multiple transverse-radial propellers or a propulsion system for producing a lift force and thrust force on the stationary or non-stationary FW. This VTOL/FWA is capable of exchanging payloads horizontally, as well as vertically, with a stationary or a moving object. In particular, the VTOL/FWA can “walk” on a building wall to adjust and anchor its position in order to rescue people from a high-rise-building window horizontally.

A vertical take-off and landing (“VTOL”) aircraft has at least two flying wings (“FW”) with each FW equipped with multiple transverse-radial propellers or a propulsion system for producing a lift force and thrust force on the stationary or non-stationary FW. This VTOL/FWA is capable of exchanging payloads horizontally, as well as vertically, with a stationary or a moving object. In particular, the VTOL/FWA can “walk” on a building wall to adjust and anchor its position in order to rescue people from a high-rise-building window horizontally.

According to one implementation, a rotorcraft includes rotors, a fuselage, at least three rods, at least one load sensor and a control device. The rotors obtain lift. The fuselage is coupled to the rotors. The at least three rods support the fuselage. The at least one load sensor detects loads applied on the at least three rods. The control device automatically controls the rotors so that measured values of the loads detected by the at least one load sensor are brought to targeted values of the loads.

An air transport vehicle that capitalizes on the strengths and complexities of a fixed and rotary winged aircraft. The air transport vehicle comprises a body aerodynamically designed to avoid substantial drag. The vehicle has a plurality of rotors configured to generate vertical thrust with a rear rotor configured to generate forward thrust. Additionally, each of the rotors are connected to the fixed wing elements and the fixed wing is positioned about the center of mass of the fuselage. Furthermore, each of the rotors are positioned at a fixed tilt angle such that the stability of the vehicle is maintained in a number of different flight configurations.