A method for controlling an unmanned aerial vehicle (UAV) is described. In one example, the method includes: detecting, by one or more processors of a controller within a UAV, whether flight control surfaces of the UAV are operating nominally; switching, by the one or more processors of the controller, in response to detecting that one or more of the flight control surfaces of the UAV are not operating nominally, to implementing a backup control mode configured to operate the UAV in flight with non-nominal operability of one or more of the control surfaces of the UAV; and operating, by the one or more processors of the controller, the UAV in the backup control mode.

Described herein are systems, devices, methods, computer-readable media, techniques, and methodologies for object retrieval and delivery using an unmanned aerial vehicle (UAV) such as a drone. The UAV receives user input from a user such as audial input and processes the input to determine a user command. The user command can be a command to retrieve an object that is out of reach of the user. The UAV scans the environment capturing image data using on-board sensors. The image data can be fed to a neural network trained in object detection to identify the object in the environment. Once identified, the UAV can then navigate to the object, retrieve the object, and deliver the object to a target individual or location such as a location adjacent to the user.

A system for tracking a below-ground transmitter from an aerial receiver. The receiver has an antenna assembly, a processor, and a propulsion system. The antenna assembly detects the magnetic field from an underground transmitter and generates an antenna signal. The processor is programmed to receive the antenna signal and generate a command signal, which moves the receiver to a position above the transmitter. Once in the desired position, which may be a reference plane at a fixed elevation, the antenna assembly measures the magnetic field to determine the location of the drill bit along borepath.

A configurable unmanned aerial vehicle (UAV) may include swappable avionics that may be selectable for use with other UAV components to build a customized UAV just prior to deployment of the UAV that is configured to deliver a package to a destination. Various factors may be involved in the selection of the avionics, such as an availability of different avionics, payload requirements (size, weight, etc.), environmental conditions along an anticipated route of flight, a region of use of the UAV, compatibility, a distance of the flight, power considerations, security considerations, and/or other factors. The avionics may include various hardware and/or software which may provide control output (e.g., data, power, and/or mechanical) to other components and/or systems, including a propulsion system. Coupling devices may selectively couple the avionics to other components of the UAV, such as to a battery, a cargo bay or package, and/or to a propulsion system.

An unmanned aerial vehicle (UAV) is provided including a fuselage, a pair of wings extending outwardly from the fuselage, and a deployable surface moveable from a first undeployed position during normal flight to a second deployed position when there is a system failure during flight. A method of adjusting a center of pressure of a UAV is also provided including the steps of providing a UAV with a fuselage, a pair of wings extending outwardly from the fuselage, and a deployable surface moveable from a first undeployed position during normal flight to a second deployed position when there is a system failure during flight, sensing when there is a system failure, and moving the deployable surface from the first undeployed position to the second deployed position.

An embodiment of the present disclosure provides an unmanned aerial vehicle, An unmanned aerial vehicle, with a double-layered structure formed by stacking a cover and a main component layer, wherein, the main component layer includes a base body and at least one functional component, the base body has a top facing to the cover layer and a bottom opposite to the top, the cover is in direct contact with the top of the base body, and the at least one functional component is mounted on the base body.

A vehicle control system may include a vehicle frame, a mount secured to the vehicle frame and configured for rigidly securing a smartphone therein such that motions experienced by the vehicle frame are correspondingly experienced by the smartphone, and system electronics arranged on the frame and in communication with the smartphone and vehicle controllers, the system electronics configured to receive signals from the smartphone and control directional devices of the vehicle based on the signals via the vehicle controllers. A system for preparing signals for transmission to the vehicle to control navigation may also be provided.

A method of redistributing motor power of an unmanned aerial vehicle (UAV) includes determining, with aid of one or more processors, an operating state of a motor of the UAV. The motor is configured to drive a corresponding rotor to generate lift for the UAV. The method further includes determining, with aid of the one or more processors, how to redistribute power from the motor between a plurality of components when the motor has an operating state that is a decelerating state, and redistributing the power in accordance with the determination of how to redistribute the power.

In some embodiments, methods and systems are provided that provide for creating and monitoring predefined mission routes along air rails and non-overlapping buffer zones surrounding unmanned vehicles during travel of the unmanned vehicles along the predefined mission routes. The buffer zone may be thought of as a projected movement variation area being associated by the system to the UAV and containing four dimensions, the three positional dimensions, X, Y, and Z, along with a temporal one, time. Generally, the buffer zone will change as ambient conditions, location, and orientation of an unmanned vehicle change during travel of the unmanned vehicle along its predefined mission route.

A method, apparatus, and system for automating detection and avoidance for an aircraft. A process activates a set of lamps visible on an exterior of an aircraft to emit light. The process modulates an intensity of light from the set of lamps at a set of frequencies that is detectable by a remote collision avoidance system in a remote aircraft during flight. The light from the set of lamps at the set of frequencies is perceived as continuous by a person looking at the aircraft in a sky, reducing visibility of the aircraft in the sky.