A navigation system for an aircraft includes a light source, a light sensor, one or more processors, and a computer readable medium storing instructions that, when executed by the one or more processors, cause the navigation system to perform functions. The functions include illuminating a surface using the light source to cause light to be reflected from the surface and detecting the light and generating data representing the light using the light sensor. The data maps intensities of the light to respective positions on the surface. The functions further include identifying within the data a subset of the data that corresponds to a border and causing navigation of the aircraft based on a position of the border indicated by the subset of the data.

A navigation system for an aircraft includes a light source, a light sensor, one or more processors, and a computer readable medium storing instructions that, when executed by the one or more processors, cause the navigation system to perform functions. The functions include illuminating a surface using the light source to cause light to be reflected from the surface and detecting the light and generating data representing the light using the light sensor. The data maps intensities of the light to respective positions on the surface. The functions further include identifying within the data a subset of the data that corresponds to a border and causing navigation of the aircraft based on a position of the border indicated by the subset of the data.

A navigation system for an aircraft includes a light source, a light sensor, one or more processors, and a computer readable medium storing instructions that, when executed by the one or more processors, cause the navigation system to perform functions. The functions include illuminating a surface using the light source to cause light to be reflected from the surface and detecting the light and generating data representing the light using the light sensor. The data maps intensities of the light to respective positions on the surface. The functions further include identifying within the data a subset of the data that corresponds to a border and causing navigation of the aircraft based on a position of the border indicated by the subset of the data.

A navigation system for an aircraft includes a light source, a light sensor, one or more processors, and a computer readable medium storing instructions that, when executed by the one or more processors, cause the navigation system to perform functions. The functions include illuminating a surface using the light source to cause light to be reflected from the surface and detecting the light and generating data representing the light using the light sensor. The data maps intensities of the light to respective positions on the surface. The functions further include identifying within the data a subset of the data that corresponds to a border and causing navigation of the aircraft based on a position of the border indicated by the subset of the data.

Aerial navigation is disclosed. A system can detect a difference between forces applied to a plurality of ground contact points of an aerial vehicle taxiing on a ground surface. The system can determine an adjustment to a vertical component of a thrust. The thrust can be produced by at least one of a rotor or a propeller of the aerial vehicle to reduce the difference between the forces applied to the plurality of ground contact points of the aerial vehicle. The system can generate a control output to cause the at least one of the rotor or the propeller to adjust the vertical component of the thrust to reduce the difference between the forces.

Aerial navigation is disclosed. A system can detect a difference between forces applied to a plurality of ground contact points of an aerial vehicle taxiing on a ground surface. The system can determine an adjustment to a vertical component of a thrust. The thrust can be produced by at least one of a rotor or a propeller of the aerial vehicle to reduce the difference between the forces applied to the plurality of ground contact points of the aerial vehicle. The system can generate a control output to cause the at least one of the rotor or the propeller to adjust the vertical component of the thrust to reduce the difference between the forces.

Disclosed is a ground movement system for a helicopter having a fuselage and rotor blades fixed to the top of the fuselage, the ground movement system comprising at least three wheels secured below the fuselage of the helicopter, the wheels being retractable during flight; a motor positioned in the hub or on the undercarriage leg of each of at least two of the wheels, wherein each motor is operable to rotate the wheel in forward and backward directions; wherein each motor allows the wheel to rotate freely when unpowered; at least one user interface operable to receive user input commands to control the speed and direction of travel of the helicopter using the ground movement system; and a control arrangement to provide control signals to each of the motors based on the user input commands.

Disclosed is a ground movement system for a helicopter having a fuselage and rotor blades fixed to the top of the fuselage, the ground movement system comprising at least three wheels secured below the fuselage of the helicopter, the wheels being retractable during flight; a motor positioned in the hub or on the undercarriage leg of each of at least two of the wheels, wherein each motor is operable to rotate the wheel in forward and backward directions; wherein each motor allows the wheel to rotate freely when unpowered; at least one user interface operable to receive user input commands to control the speed and direction of travel of the helicopter using the ground movement system; and a control arrangement to provide control signals to each of the motors based on the user input commands.

An unmanned aircraft traction control system without a traction rod and an intelligent tractor relate to the technical fields of aircraft ground motion and man-machine coordination. The traction control system includes an aircraft light identification and induction module, a main sensing system module, an aircraft sound identification and induction module and a control module which are arranged on the tractor. When the tractor and an aircraft carry out a wheel holding operation, the aircraft light identification and induction module, the main sensing system module and the aircraft sound identification and induction module acquire a brightness signal of an aircraft nose landing gear taxi light, an aircraft turning signal, an aircraft resistance signal and an aircraft horn signal autonomously transmitted by a pilot. The purpose that a pilot autonomously controls the tractor to pull an aircraft to an aircraft parking position or a designated taxiway position is realized through the above signals.

An unmanned aircraft traction control system without a traction rod and an intelligent tractor relate to the technical fields of aircraft ground motion and man-machine coordination. The traction control system includes an aircraft light identification and induction module, a main sensing system module, an aircraft sound identification and induction module and a control module which are arranged on the tractor. When the tractor and an aircraft carry out a wheel holding operation, the aircraft light identification and induction module, the main sensing system module and the aircraft sound identification and induction module acquire a brightness signal of an aircraft nose landing gear taxi light, an aircraft turning signal, an aircraft resistance signal and an aircraft horn signal autonomously transmitted by a pilot. The purpose that a pilot autonomously controls the tractor to pull an aircraft to an aircraft parking position or a designated taxiway position is realized through the above signals.