Title :
Actuator fault-tolerant control based on Gain-Scheduled PID with application to fixed-wing Unmanned Aerial Vehicle
Author :
Sadeghzadeh, Iman ; Youmin Zhang
Author_Institution :
Dept. of Mech. & Ind. Eng., Concordia Univ., Montreal, QC, Canada
Abstract :
This paper focuses on the application of widely used Proportional-Integral-Derivative (PID) technique to control an unmanned fixed-wing airplane for fault-free and faulty scenarios. The PID controller is used to control all six variables separately, which are Roll, Pitch, Yaw (Euler angles), X, Y and Z (Navigation). For fault cases, the Gain-Scheduled PID (GS-PID) control strategy is used to handle the hard-over fault which is injected to UAV´s split rudder control surface for achieving fault-tolerant control. Different sets of pre-tuned PID gains are designed for different parts of flight envelope and fault cases.
Keywords :
actuators; aerospace components; aircraft control; autonomous aerial vehicles; control system synthesis; fault tolerant control; three-term control; Euler angles; GS-PID control strategy; UAV split rudder control surface; actuator fault-tolerant control; fault-free scenarios; faulty scenarios; fixed-wing unmanned aerial vehicle; flight envelope; gain-scheduled PID control strategy; hard-over fault; pitch control; pretuned PID gain design; proportional-integral-derivative technique; roll control; unmanned fixed-wing airplane control; yaw control; Batteries; Battery charge measurement; Fault diagnosis; Global Positioning System; Loading;
Conference_Titel :
Control and Fault-Tolerant Systems (SysTol), 2013 Conference on
Conference_Location :
Nice
DOI :
10.1109/SysTol.2013.6693957
