Abstract: Methods and apparatus for enhancing aircraft flight control surface effectiveness via forced oscillation are described. An example control system of an aircraft includes a flight control surface, an actuator, and one or more processors. The actuator is configured to move the flight control surface. The one or more processors are configured to determine a current position of the flight control surface. The one or more processors are further configured to determine whether the current position exceeds a position threshold. The one or more processors are further configured to generate a forced oscillation signal in response to determining that the current position exceeds the position threshold. The one or more processors are further configured to command the actuator to move the flight control surface based on the forced oscillation signal.

Abstract: Methods and apparatus for enhancing aircraft flight control surface effectiveness via forced oscillation are described. An example control system of an aircraft includes a flight control surface, an actuator, and one or more processors. The actuator is configured to move the flight control surface. The one or more processors are configured to determine a current position of the flight control surface. The one or more processors are further configured to determine whether the current position exceeds a position threshold. The one or more processors are further configured to generate a forced oscillation signal in response to determining that the current position exceeds the position threshold. The one or more processors are further configured to command the actuator to move the flight control surface based on the forced oscillation signal.

Abstract: Systems and methods are described for changing the performance of an aircraft by customizing aircraft control system parameters based on a subjective personal preference of a pilot. The system includes a user interface for receiving the customized aircraft control system parameters from the pilot. A first aircraft control module may receive the customized aircraft control system parameters from the user interface, and also receive flight control commands from the pilot. The received flight control commands and the received customized aircraft control system parameters may be processed by the first aircraft control module to cause the aircraft to perform according to customized characteristics as determined by the pilot.

Abstract: Systems and methods are described for changing the performance of an aircraft by customizing aircraft control system parameters based on a subjective personal preference of a pilot. The system includes a user interface for receiving the customized aircraft control system parameters from the pilot. A first aircraft control module may receive the customized aircraft control system parameters from the user interface, and also receive flight control commands from the pilot. The received flight control commands and the received customized aircraft control system parameters may be processed by the first aircraft control module to cause the aircraft to perform according to customized characteristics as determined by the pilot.

Abstract: Methods, systems, and articles of manufacture determine the position of a reference point relative to a vehicle. The reference point includes a transmitter operatively configured to transmit a first waveform and a second waveform having a relationship with the first waveform. The vehicle has a plurality of receivers disposed at a plurality of locations relative to the vehicle. The first waveform is detected by each of the receivers. The second waveform is detected by at least three of the receivers, each of which detects a respective number of cycles of the second waveform between the time the first receiver detects the first waveform and when the first waveform is detected by the respective receiver. The reference point position is calculated using a triangulation technique based on each of the identified number of cycles and each location of the receivers detecting the second waveform.

Abstract: A measurement-based method to control and optimize the performance of an airborne vehicle. The stability and control of the vehicle is modified to induce a response in the airborne vehicle as reflected by a plurality of response signals. Excitations signals having multi-term sinusoidal waveforms are generated and applied to control signals controlling one or more control effectors. A time domain response of each of the state variables, response signals, and control signals arising from the application of the excitation inputs to the control signals is then measured. These time domain responses are then transformed into frequency domain models. The effectiveness and vehicle stability and control derivatives may then be identified from the frequency domain models of the state variables, response signals, and control signals.