Title :
Robust control of two-wheeled self-balanced transporter on sloping ground: A Takagi-Sugeno descriptor approach
Author :
Allouche, Benyamine ; Vermeiren, Laurent ; Dequidt, Antoine ; Dambrine, Michel
Author_Institution :
LAMIH, UVHC, Valenciennes, France
Abstract :
A commonly asked question in the field of autonomous robotics and intelligent vehicles is: How to design and control an urban transporter able to investigate narrow spaces? From a mechanical point of view, a two wheeled transporter seems to be a good alternative due to its small footprint and its ability to manoeuvre on tight turns. However, the design of this vehicle requires two level of control: One, for the auto-balancing. The second ensures a velocity tracking. The use of linear control law requires a linearisation of the model around an a priori known equilibrium point under the assumption that the vehicle moves on a plane surface. Now, assume that the vehicle is moving along an unknown slope. Then, the equilibrium point is not known while designing the controller. The linearized model becomes unrepresentative. This work present a control of self-balanced two wheeled transporter. The aim is to design a robust controller able to stabilize the transporter on its natural equilibrium along an unknown slope. A quasi LPV approach, through the so-called TS fuzzy model and LMI constraints will be proposed. Moreover, The natural descriptor form of the mechanical system will be used to design the control law. This last choice allows reducing the conservatism of the LMI conditions. Finally a simulation tests showed the effectiveness of our approach.
Keywords :
control system synthesis; fuzzy control; linear matrix inequalities; linear systems; linearisation techniques; mechanical variables control; road vehicles; robust control; time-varying systems; velocity control; wheels; LMI conditions; LMI constraints; Takagi-Sugeno descriptor approach; Takagi-Sugeno fuzzy model; auto-balancing control; autonomous robotics; controller design; equilibrium point; intelligent vehicles; linear control law; linear matrix inequalities; linear parameter varying approach; linearisation; mechanical point-of-view; quasiLPV approach; robust control; sloping ground; stability; two-wheeled self-balanced transporter; urban transporter; vehicle design; velocity tracking control; Mathematical model; PD control; Robustness; Takagi-Sugeno model; Uncertainty; Vectors; Vehicles;
Conference_Titel :
Systems and Control (ICSC), 2013 3rd International Conference on
Conference_Location :
Algiers
Print_ISBN :
978-1-4799-0273-6
DOI :
10.1109/ICoSC.2013.6750885