Finite Element-Based Control of a Single-Link Flexible Hydraulic Manipulator

Petri Mäkinen; Jouni Mattila

doi:10.1115/FPMC2017-4264

Finite Element-Based Control of a Single-Link Flexible Hydraulic Manipulator

Petri Mäkinen
, Jouni Mattila

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

9 Citations (Scopus)

Abstract

In this study, a stability-guaranteed, nonlinear, finite element-based control is presented for a single-link flexible manipulator with hydraulic actuation, subject to experimental validation. The strong, inherent nonlinearities of the hydraulic cylinder and fluid dynamics, coupled with flexible link dynamics, cause remarkable challenges in controlling the system effectively. In an attempt to cope with these challenges, a controller based on the Virtual Decomposition Control (VDC) approach is introduced. The VDC approach takes advantage of subsystem-dynamics-based control, enabling the handling of the dynamics and control of the hydraulic actuator and the flexible link separately, thus keeping the controller design relatively simple. The rigorous stability theory of the VDC approach guarantees the stability of the entire system. The experiments demonstrate the VDC controller’s performance in end-point control with built-in vibration dampening.

Original language	English
Title of host publication	ASME/BATH 2017 Symposium on Fluid Power and Motion Control
Publisher	ASME
Number of pages	10
ISBN (Electronic)	978-0-7918-5833-2
DOIs	https://doi.org/10.1115/FPMC2017-4264
Publication status	Published - Oct 2017
Publication type	A4 Article in conference proceedings
Event	ASME/BATH Symposium on Fluid Power and Motion Control - , United Kingdom Duration: 1 Jan 1900 → …

Conference

Conference	ASME/BATH Symposium on Fluid Power and Motion Control
Country/Territory	United Kingdom
Period	1/01/00 → …

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title = "Finite Element-Based Control of a Single-Link Flexible Hydraulic Manipulator",

abstract = "In this study, a stability-guaranteed, nonlinear, finite element-based control is presented for a single-link flexible manipulator with hydraulic actuation, subject to experimental validation. The strong, inherent nonlinearities of the hydraulic cylinder and fluid dynamics, coupled with flexible link dynamics, cause remarkable challenges in controlling the system effectively. In an attempt to cope with these challenges, a controller based on the Virtual Decomposition Control (VDC) approach is introduced. The VDC approach takes advantage of subsystem-dynamics-based control, enabling the handling of the dynamics and control of the hydraulic actuator and the flexible link separately, thus keeping the controller design relatively simple. The rigorous stability theory of the VDC approach guarantees the stability of the entire system. The experiments demonstrate the VDC controller{\textquoteright}s performance in end-point control with built-in vibration dampening.",

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AU - Mattila, Jouni

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N2 - In this study, a stability-guaranteed, nonlinear, finite element-based control is presented for a single-link flexible manipulator with hydraulic actuation, subject to experimental validation. The strong, inherent nonlinearities of the hydraulic cylinder and fluid dynamics, coupled with flexible link dynamics, cause remarkable challenges in controlling the system effectively. In an attempt to cope with these challenges, a controller based on the Virtual Decomposition Control (VDC) approach is introduced. The VDC approach takes advantage of subsystem-dynamics-based control, enabling the handling of the dynamics and control of the hydraulic actuator and the flexible link separately, thus keeping the controller design relatively simple. The rigorous stability theory of the VDC approach guarantees the stability of the entire system. The experiments demonstrate the VDC controller’s performance in end-point control with built-in vibration dampening.

AB - In this study, a stability-guaranteed, nonlinear, finite element-based control is presented for a single-link flexible manipulator with hydraulic actuation, subject to experimental validation. The strong, inherent nonlinearities of the hydraulic cylinder and fluid dynamics, coupled with flexible link dynamics, cause remarkable challenges in controlling the system effectively. In an attempt to cope with these challenges, a controller based on the Virtual Decomposition Control (VDC) approach is introduced. The VDC approach takes advantage of subsystem-dynamics-based control, enabling the handling of the dynamics and control of the hydraulic actuator and the flexible link separately, thus keeping the controller design relatively simple. The rigorous stability theory of the VDC approach guarantees the stability of the entire system. The experiments demonstrate the VDC controller’s performance in end-point control with built-in vibration dampening.

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DO - 10.1115/FPMC2017-4264

M3 - Conference contribution

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T2 - ASME/BATH Symposium on Fluid Power and Motion Control

Y2 - 1 January 1900

ER -

Finite Element-Based Control of a Single-Link Flexible Hydraulic Manipulator

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