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Autori principali: Ma, Shuhao, Cao, Yu, Robertson, Ian D., Shi, Chaoyang, Liu, Jindong, Zhang, Zhi-Qiang
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2412.05403
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author Ma, Shuhao
Cao, Yu
Robertson, Ian D.
Shi, Chaoyang
Liu, Jindong
Zhang, Zhi-Qiang
author_facet Ma, Shuhao
Cao, Yu
Robertson, Ian D.
Shi, Chaoyang
Liu, Jindong
Zhang, Zhi-Qiang
contents Accurate understanding of muscle activation and muscle forces plays an essential role in neuro-rehabilitation and musculoskeletal disorder treatments. Computational musculoskeletal modeling has been widely used as a powerful non-invasive tool to estimate them through inverse dynamics using static optimization, but the inherent computational complexity results in time-consuming analysis. In this paper, we propose a knowledge-based deep learning framework for time-efficient inverse dynamic analysis, which can predict muscle activation and muscle forces from joint kinematic data directly while not requiring any label information during model training. The Bidirectional Gated Recurrent Unit (BiGRU) neural network is selected as the backbone of our model due to its proficient handling of time-series data. Prior physical knowledge from forward dynamics and pre-selected inverse dynamics based physiological criteria are integrated into the loss function to guide the training of neural networks. Experimental validations on two datasets, including one benchmark upper limb movement dataset and one self-collected lower limb movement dataset from six healthy subjects, are performed. The experimental results have shown that the selected BiGRU architecture outperforms other neural network models when trained using our specifically designed loss function, which illustrates the effectiveness and robustness of the proposed framework.
format Preprint
id arxiv_https___arxiv_org_abs_2412_05403
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Knowledge-Based Deep Learning for Time-Efficient Inverse Dynamics
Ma, Shuhao
Cao, Yu
Robertson, Ian D.
Shi, Chaoyang
Liu, Jindong
Zhang, Zhi-Qiang
Signal Processing
Computational Engineering, Finance, and Science
Human-Computer Interaction
Machine Learning
Biological Physics
Accurate understanding of muscle activation and muscle forces plays an essential role in neuro-rehabilitation and musculoskeletal disorder treatments. Computational musculoskeletal modeling has been widely used as a powerful non-invasive tool to estimate them through inverse dynamics using static optimization, but the inherent computational complexity results in time-consuming analysis. In this paper, we propose a knowledge-based deep learning framework for time-efficient inverse dynamic analysis, which can predict muscle activation and muscle forces from joint kinematic data directly while not requiring any label information during model training. The Bidirectional Gated Recurrent Unit (BiGRU) neural network is selected as the backbone of our model due to its proficient handling of time-series data. Prior physical knowledge from forward dynamics and pre-selected inverse dynamics based physiological criteria are integrated into the loss function to guide the training of neural networks. Experimental validations on two datasets, including one benchmark upper limb movement dataset and one self-collected lower limb movement dataset from six healthy subjects, are performed. The experimental results have shown that the selected BiGRU architecture outperforms other neural network models when trained using our specifically designed loss function, which illustrates the effectiveness and robustness of the proposed framework.
title Knowledge-Based Deep Learning for Time-Efficient Inverse Dynamics
topic Signal Processing
Computational Engineering, Finance, and Science
Human-Computer Interaction
Machine Learning
Biological Physics
url https://arxiv.org/abs/2412.05403