Trajectory Planning for a Segway Model Exploiting Inherent Feedforward Structure

Christian Zauner; Andreas Müller; Hubert Gattringer; Matthias Jörgl

Trajectory Planning for a Segway Model Exploiting Inherent Feedforward Structure

Christian Zauner, Andreas Müller, Hubert Gattringer, Matthias Jörgl

Institute of Robotics

Research output: Chapter in Book/Report/Conference proceeding › Conference proceedings › peer-review

Abstract

Time/energy optimal trajectory planning for a Segway model (inverted pendulum on two independently actuated wheels) is addressed. Basis for this planning is the dynamical model for this under-actuated, non-holonomic multibody system. In order to reduce the calculation effort for the optimization, an input/output transformation is applied, which leads to a control system in strict feedforward form. The full system state can thus be described by two outputs, which are parameterized by two B-splines. The system is required to move on the ground within a predefined area. For the optimization the control points of the B-Splines serve as optimization variables and the cost functional is comprised of the overall energy of the robot and the terminal time. Additionally to the maximum motor velocities and torques, the maximum ground reaction forces give rise to the constraints. The latter are crucial to ensure that the wheels do not slip.

Original language	English
Title of host publication	Tagungsband 21st IFAC World Congress
Number of pages	6
Publication status	Published - 2020

Fields of science

203015 Mechatronics
203022 Technical mechanics
202 Electrical Engineering, Electronics, Information Engineering
202035 Robotics
203013 Mechanical engineering

JKU Focus areas

Digital Transformation

Cite this

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title = "Trajectory Planning for a Segway Model Exploiting Inherent Feedforward Structure",

abstract = "Time/energy optimal trajectory planning for a Segway model (inverted pendulum on two independently actuated wheels) is addressed. Basis for this planning is the dynamical model for this under-actuated, non-holonomic multibody system. In order to reduce the calculation effort for the optimization, an input/output transformation is applied, which leads to a control system in strict feedforward form. The full system state can thus be described by two outputs, which are parameterized by two B-splines. The system is required to move on the ground within a predefined area. For the optimization the control points of the B-Splines serve as optimization variables and the cost functional is comprised of the overall energy of the robot and the terminal time. Additionally to the maximum motor velocities and torques, the maximum ground reaction forces give rise to the constraints. The latter are crucial to ensure that the wheels do not slip.",

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AU - Zauner, Christian

AU - Müller, Andreas

AU - Gattringer, Hubert

AU - Jörgl, Matthias

PY - 2020

Y1 - 2020

N2 - Time/energy optimal trajectory planning for a Segway model (inverted pendulum on two independently actuated wheels) is addressed. Basis for this planning is the dynamical model for this under-actuated, non-holonomic multibody system. In order to reduce the calculation effort for the optimization, an input/output transformation is applied, which leads to a control system in strict feedforward form. The full system state can thus be described by two outputs, which are parameterized by two B-splines. The system is required to move on the ground within a predefined area. For the optimization the control points of the B-Splines serve as optimization variables and the cost functional is comprised of the overall energy of the robot and the terminal time. Additionally to the maximum motor velocities and torques, the maximum ground reaction forces give rise to the constraints. The latter are crucial to ensure that the wheels do not slip.

AB - Time/energy optimal trajectory planning for a Segway model (inverted pendulum on two independently actuated wheels) is addressed. Basis for this planning is the dynamical model for this under-actuated, non-holonomic multibody system. In order to reduce the calculation effort for the optimization, an input/output transformation is applied, which leads to a control system in strict feedforward form. The full system state can thus be described by two outputs, which are parameterized by two B-splines. The system is required to move on the ground within a predefined area. For the optimization the control points of the B-Splines serve as optimization variables and the cost functional is comprised of the overall energy of the robot and the terminal time. Additionally to the maximum motor velocities and torques, the maximum ground reaction forces give rise to the constraints. The latter are crucial to ensure that the wheels do not slip.

M3 - Conference proceedings

BT - Tagungsband 21st IFAC World Congress

ER -