Elbow motion trajectory prediction using a multi-modal wearable system : a comparative analysis of machine learning techniques
Motion intention detection is fundamental in the implementation of human-machine interfaces applied to assistive robots. In this paper, multiple machine learning techniques have been explored for creating upper limb motion prediction models, which generally depend on three factors: the signals colle...
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sg-ntu-dr.10356-1474092023-03-04T17:11:46Z Elbow motion trajectory prediction using a multi-modal wearable system : a comparative analysis of machine learning techniques Little, Kieran Pappachan, Bobby Kaniyamkudy Yang, Sibo Noronha, Bernardo Campolo, Domenico Accoto, Dino School of Mechanical and Aerospace Engineering Robotics Research Centre Engineering::Mechanical engineering Motion Intention Detection Assistive Robotics Motion intention detection is fundamental in the implementation of human-machine interfaces applied to assistive robots. In this paper, multiple machine learning techniques have been explored for creating upper limb motion prediction models, which generally depend on three factors: the signals collected from the user (such as kinematic or physiological), the extracted features and the selected algorithm. We explore the use of different features extracted from various signals when used to train multiple algorithms for the prediction of elbow flexion angle trajectories. The accuracy of the prediction was evaluated based on the mean velocity and peak amplitude of the trajectory, which are sufficient to fully define it. Results show that prediction accuracy when using solely physiological signals is low, however, when kinematic signals are included, it is largely improved. This suggests kinematic signals provide a reliable source of information for predicting elbow trajectories. Different models were trained using 10 algorithms. Regularization algorithms performed well in all conditions, whereas neural networks performed better when the most important features are selected. The extensive analysis provided in this study can be consulted to aid in the development of accurate upper limb motion intention detection models. Agency for Science, Technology and Research (A*STAR) Published version This work was partially supported by the grant “Intelligent Human-Robot interface for upper limb wearable robots” (Award Number SERC1922500046, A*STAR, Singapore). 2021-03-31T06:10:22Z 2021-03-31T06:10:22Z 2021 Journal Article Little, K., Pappachan, B. K., Yang, S., Noronha, B., Campolo, D. & Accoto, D. (2021). Elbow motion trajectory prediction using a multi-modal wearable system : a comparative analysis of machine learning techniques. Sensors, 21(2). https://dx.doi.org/10.3390/s21020498 1424-8220 https://hdl.handle.net/10356/147409 10.3390/s21020498 33445601 2-s2.0-85099302074 2 21 en SERC1922500046 Sensors © 2021 The Author(s). Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/). application/pdf |
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Engineering::Mechanical engineering Motion Intention Detection Assistive Robotics Little, Kieran Pappachan, Bobby Kaniyamkudy Yang, Sibo Noronha, Bernardo Campolo, Domenico Accoto, Dino Elbow motion trajectory prediction using a multi-modal wearable system : a comparative analysis of machine learning techniques |
| description |
Motion intention detection is fundamental in the implementation of human-machine interfaces applied to assistive robots. In this paper, multiple machine learning techniques have been explored for creating upper limb motion prediction models, which generally depend on three factors: the signals collected from the user (such as kinematic or physiological), the extracted features and the selected algorithm. We explore the use of different features extracted from various signals when used to train multiple algorithms for the prediction of elbow flexion angle trajectories. The accuracy of the prediction was evaluated based on the mean velocity and peak amplitude of the trajectory, which are sufficient to fully define it. Results show that prediction accuracy when using solely physiological signals is low, however, when kinematic signals are included, it is largely improved. This suggests kinematic signals provide a reliable source of information for predicting elbow trajectories. Different models were trained using 10 algorithms. Regularization algorithms performed well in all conditions, whereas neural networks performed better when the most important features are selected. The extensive analysis provided in this study can be consulted to aid in the development of accurate upper limb motion intention detection models. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Little, Kieran Pappachan, Bobby Kaniyamkudy Yang, Sibo Noronha, Bernardo Campolo, Domenico Accoto, Dino |
| format |
Article |
| author |
Little, Kieran Pappachan, Bobby Kaniyamkudy Yang, Sibo Noronha, Bernardo Campolo, Domenico Accoto, Dino |
| author_sort |
Little, Kieran |
| title |
Elbow motion trajectory prediction using a multi-modal wearable system : a comparative analysis of machine learning techniques |
| title_short |
Elbow motion trajectory prediction using a multi-modal wearable system : a comparative analysis of machine learning techniques |
| title_full |
Elbow motion trajectory prediction using a multi-modal wearable system : a comparative analysis of machine learning techniques |
| title_fullStr |
Elbow motion trajectory prediction using a multi-modal wearable system : a comparative analysis of machine learning techniques |
| title_full_unstemmed |
Elbow motion trajectory prediction using a multi-modal wearable system : a comparative analysis of machine learning techniques |
| title_sort |
elbow motion trajectory prediction using a multi-modal wearable system : a comparative analysis of machine learning techniques |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/147409 |
| _version_ |
1759857286225854464 |