The area of autonomous underwater vehicles (AUVs) is an increasingly important area of
research, with AUVs being capable of handling a far wider range of missions than either
an inhabited underwater vehicle or a remotely operated vehicle (ROV). One of the major
drawbacks of such vehicles is the inability of their control systems to handle faults
occurring within the vehicle during a mission. This study aims to develop enhancements
to an existing control system in order to increase its fault tolerance to both sensor and
actuator faults.
Faults occurring within the sensors for both the yaw and roll channels of the AUV are
considered. Novel fuzzy inference systems (FISs) are developed and tuned using both the
adaptive neuro-fuzzy inference system (ANFIS) and simulated annealing tuning methods.
These FISs allow the AUV to continue operating after a fault has occurred within the
sensors.
Faults occurring within the actuators which control the canards of the AUV and hence the
yaw channel are also examined. Actuator recovery FISs capable of handling faults
occurring within the actuators are developed using both the simulated annealing and tabu
search methods of tuning FISs. The fault tolerance of the AUV is then further enhanced
by the development of an error estimation FIS that is used to replace an error sensor.
It concludes that the novel FISs designed and developed within the thesis provide an
improved performance to both sensor and actuator faults in comparison to benchmark
control systems. Therefore having these FISs embedded within the overall control
scheme ensure the AUV is fault tolerant to a range of selected failures.
Date of Award | 2002 |
---|
Original language | English |
---|
Awarding Institution | |
---|
INTELLIGENT FAULT TOLERANT CONTROL SCHEMES FOR AUTONOMOUS UNDERWATER VEHICLES
PEARSON, A. R. (Author). 2002
Student thesis: PhD