Title :
Adaptive backstepping and MEMS force sensor for an MRI-guided microrobot in the vasculature
Author :
Arcese, Laurent ; Fruchard, Matthieu ; Beyeler, Felix ; Ferreira, Antoine ; Nelson, Bradley J.
Author_Institution :
Lab. PRISME, Univ. d´´Orleans, Bourges, France
Abstract :
-A microrobot consisting of a polymer binded aggregate of ferromagnetic particles is controlled using a Magnetic Resonance Imaging (MRI) device in order to achieve targeted therapy. The primary contribution of this paper is the design of an adaptive backstepping controller coupled with a high gain observer based on a nonlinear model of a microrobot in a blood vessel. This work is motivated by the difficulty in accurately determining many biological parameters, which can result in parametric uncertainties to which model-based approaches are highly sensitive. We show that the most sensitive parameter, magnetization of the microrobot, can be measured using a Micro-Electro-Mechanical Systems (MEMS) force sensor, while the second one, the dielectric constant of blood, can be estimated on line. The efficacy of this approach is illustrated by simulation results.
Keywords :
adaptive control; biomedical MRI; blood vessels; cardiovascular system; ferromagnetic materials; force sensors; magnetisation; microrobots; microsensors; nonlinear control systems; observers; uncertain systems; MEMS force sensor; MRI; adaptive backstepping controller; blood vessel; dielectric constant; ferromagnetic particles; gain observer; guided microrobot; magnetic resonance imaging; magnetization; microelectromechanical systems; model based approach; nonlinear model; parametric uncertainty; vasculature; Blood; Force; Magnetic resonance imaging; Magnetization; Observers; Robots; Saturation magnetization;
Conference_Titel :
Robotics and Automation (ICRA), 2011 IEEE International Conference on
Conference_Location :
Shanghai
Print_ISBN :
978-1-61284-386-5
DOI :
10.1109/ICRA.2011.5979954
