Saved in:
Bibliographic Details
Main Authors: Manzl, Peter, Humer, Alexander, Khadim, Qasim, Gerstmayr, Johannes
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2409.18272
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866910237358817280
author Manzl, Peter
Humer, Alexander
Khadim, Qasim
Gerstmayr, Johannes
author_facet Manzl, Peter
Humer, Alexander
Khadim, Qasim
Gerstmayr, Johannes
contents In computational engineering, enhancing the simulation speed and efficiency is a perpetual goal. To fully take advantage of neural network techniques and hardware, we present the SLiding-window Initially-truncated Dynamic-response Estimator (SLIDE), a deep learning-based method designed to estimate output sequences of mechanical or multibody systems with primarily, but not exclusively, forced excitation. A key advantage of SLIDE is its ability to estimate the dynamic response of damped systems without requiring the full system state, making it particularly effective for flexible multibody systems. The method truncates the output window based on the decay of initial effects, such as damping, which is approximated by the complex eigenvalues of the systems linearized equations. In addition, a second neural network is trained to provide an error estimation, further enhancing the methods applicability. The method is applied to a diverse selection of systems, including the Duffing oscillator, a flexible slider-crank system, and an industrial 6R manipulator, mounted on a flexible socket. Our results demonstrate significant speedups from the simulation up to several millions, exceeding real-time performance substantially.
format Preprint
id arxiv_https___arxiv_org_abs_2409_18272
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle SLIDE: A machine-learning based method for forced dynamic response estimation of multibody systems
Manzl, Peter
Humer, Alexander
Khadim, Qasim
Gerstmayr, Johannes
Machine Learning
In computational engineering, enhancing the simulation speed and efficiency is a perpetual goal. To fully take advantage of neural network techniques and hardware, we present the SLiding-window Initially-truncated Dynamic-response Estimator (SLIDE), a deep learning-based method designed to estimate output sequences of mechanical or multibody systems with primarily, but not exclusively, forced excitation. A key advantage of SLIDE is its ability to estimate the dynamic response of damped systems without requiring the full system state, making it particularly effective for flexible multibody systems. The method truncates the output window based on the decay of initial effects, such as damping, which is approximated by the complex eigenvalues of the systems linearized equations. In addition, a second neural network is trained to provide an error estimation, further enhancing the methods applicability. The method is applied to a diverse selection of systems, including the Duffing oscillator, a flexible slider-crank system, and an industrial 6R manipulator, mounted on a flexible socket. Our results demonstrate significant speedups from the simulation up to several millions, exceeding real-time performance substantially.
title SLIDE: A machine-learning based method for forced dynamic response estimation of multibody systems
topic Machine Learning
url https://arxiv.org/abs/2409.18272