Análise comparativa de controladores robustos aplicados em robôs móvel e aéreo / Comparative analysis of robust controllers applied in mobile and aerial robots

Leão, Willian Martins

09 September 2015

Nesta dissertação é realizado um estudo comparativo entre controladores robustos projetados para sistemas lineares em espaço de estado sujeitos a incertezas paramétricas. O objetivo é resolver problemas de acompanhamento de trajetória de robôs. O estudo é realizado em um robô móvel com tração diferencial e em um quadricóptero. Para tal, é aplicado um Regulador Linear Quadrático Robusto no qual engloba em uma estrutura unificada todos os parâmetros de incerteza de entrada e saída de maneira recursiva, útil em aplicações em tempo real. A fim de demonstrar a eficiência do Regulador Robusto, resultados de simulações e de experimentos são empregados comparando-o com controle Η∞ não linear via teoria dos jogos e com um controle Proporcional-Derivativo mais torque calculado. / This work provides a comparative study between robust controllers for linear statespace systems subject to parametric uncertainties to solve trajectory tracking problems. The study is developed in a mobile robot with differential traction and in a quadricopter. A Robust Linear Quadratic Regulator is applied, which encompasses in a unified framework all input and output uncertain parameters, useful in online applications. In order to show the effectiveness of the robust regulator, simulations and experiments results allow the comparison with nonlinear Η∞ control via game theory and with a Proportional- Derivative control plus computed torque.

Controle robusto

Differential drive mobile robot

Quadricopter

Quadricóptero

Robô móvel com tração diferencial

Robust control

Análise comparativa de controladores robustos aplicados em robôs móvel e aéreo / Comparative analysis of robust controllers applied in mobile and aerial robots

Willian Martins Leão

09 September 2015

Nesta dissertação é realizado um estudo comparativo entre controladores robustos projetados para sistemas lineares em espaço de estado sujeitos a incertezas paramétricas. O objetivo é resolver problemas de acompanhamento de trajetória de robôs. O estudo é realizado em um robô móvel com tração diferencial e em um quadricóptero. Para tal, é aplicado um Regulador Linear Quadrático Robusto no qual engloba em uma estrutura unificada todos os parâmetros de incerteza de entrada e saída de maneira recursiva, útil em aplicações em tempo real. A fim de demonstrar a eficiência do Regulador Robusto, resultados de simulações e de experimentos são empregados comparando-o com controle Η∞ não linear via teoria dos jogos e com um controle Proporcional-Derivativo mais torque calculado. / This work provides a comparative study between robust controllers for linear statespace systems subject to parametric uncertainties to solve trajectory tracking problems. The study is developed in a mobile robot with differential traction and in a quadricopter. A Robust Linear Quadratic Regulator is applied, which encompasses in a unified framework all input and output uncertain parameters, useful in online applications. In order to show the effectiveness of the robust regulator, simulations and experiments results allow the comparison with nonlinear Η∞ control via game theory and with a Proportional- Derivative control plus computed torque.

Controle robusto

Quadricóptero

Robô móvel com tração diferencial

Differential drive mobile robot

Quadricopter

Robust control

Image Processing Based Control of Mobile Robotics

January 2016

abstract: Toward the ambitious long-term goal of a fleet of cooperating Flexible Autonomous Machines operating in an uncertain Environment (FAME), this thesis addresses various control objectives for ground vehicles. There are two main objectives within this thesis, first is the use of visual information to control a Differential-Drive Thunder Tumbler (DDTT) mobile robot and second is the solution to a minimum time optimal control problem for the robot around a racetrack. One method to do the first objective is by using the Position Based Visual Servoing (PBVS) approach in which a camera looks at a target and the position of the target with respect to the camera is estimated; once this is done the robot can drive towards a desired position (x_ref, z_ref). Another method is called Image Based Visual Servoing (IBVS), in which the pixel coordinates (u,v) of markers/dots placed on an object are driven towards the desired pixel coordinates (u_ref, v_ref) of the corresponding markers. By doing this, the mobile robot gets closer to a desired pose (x_ref, z_ref, theta_ref). For the second objective, a camera-based and noncamera-based (v,theta) cruise-control systems are used for the solution of the minimum time problem. To set up the minimum time problem, optimal control theory is used. Then a direct method is implemented by discretizing states and controls of the system. Finally, the solution is obtained by modeling the problem in AMPL and submitting to the nonlinear optimization solver KNITRO. Simulation and experimental results are presented. The DDTT-vehicle used within this thesis has different components as summarized below: (1) magnetic wheel-encoders/IMU for inner-loop speed-control and outer-loop directional control, (2) Arduino Uno microcontroller-board for encoder-based inner-loop speed-control and encoder-IMU-based outer-loop cruise-directional-control, (3) Arduino motor-shield for inner-loop speed-control, (4) Raspberry Pi II computer-board for outer-loop vision-based cruise-position-directional-control, (5) Raspberry Pi 5MP camera for outer-loop cruise-position-directional control. Hardware demonstrations shown in this thesis are summarized: (1) PBVS without pan camera, (2) PBVS with pan camera, (3) IBVS with 1 marker/dot, (4) IBVS with 2 markers, (5) IBVS with 3 markers, (6) camera and (7) noncamera-based (v,theta) cruise control system for the minimum time problem. / Dissertation/Thesis / Masters Thesis Electrical Engineering 2016

Electrical engineering

Mechanical engineering

Mathematics

Differential-Drive Mobile Robot

Direct Method

Image Based Visual Servoing

Minimum Time Optimal Control

Optimization

Position Based Visual Servoing