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Main Authors: Shang, Meng, Dedeyne, Lenore, Dupont, Jolan, Vercauteren, Laura, Amini, Nadjia, Lapauw, Laurence, Gielen, Evelien, Verschueren, Sabine, Varon, Carolina, De Raedt, Walter, Vanrumste, Bart
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2310.03512
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author Shang, Meng
Dedeyne, Lenore
Dupont, Jolan
Vercauteren, Laura
Amini, Nadjia
Lapauw, Laurence
Gielen, Evelien
Verschueren, Sabine
Varon, Carolina
De Raedt, Walter
Vanrumste, Bart
author_facet Shang, Meng
Dedeyne, Lenore
Dupont, Jolan
Vercauteren, Laura
Amini, Nadjia
Lapauw, Laurence
Gielen, Evelien
Verschueren, Sabine
Varon, Carolina
De Raedt, Walter
Vanrumste, Bart
contents Otago Exercise Program (OEP) is a rehabilitation program for older adults to improve frailty, sarcopenia, and balance. Accurate monitoring of patient involvement in OEP is challenging, as self-reports (diaries) are often unreliable. With the development of wearable sensors, Human Activity Recognition (HAR) systems using wearable sensors have revolutionized healthcare. However, their usage for OEP still shows limited performance. The objective of this study is to build an unobtrusive and accurate system to monitor OEP for older adults. Data was collected from older adults wearing a single waist-mounted Inertial Measurement Unit (IMU). Two datasets were collected, one in a laboratory setting, and one at the homes of the patients. A hierarchical system is proposed with two stages: 1) using a deep learning model to recognize whether the patients are performing OEP or activities of daily life (ADLs) using a 10-minute sliding window; 2) based on stage 1, using a 6-second sliding window to recognize the OEP sub-classes performed. The results showed that in stage 1, OEP could be recognized with window-wise f1-scores over 0.95 and Intersection-over-Union (IoU) f1-scores over 0.85 for both datasets. In stage 2, for the home scenario, four activities could be recognized with f1-scores over 0.8: ankle plantarflexors, abdominal muscles, knee bends, and sit-to-stand. The results showed the potential of monitoring the compliance of OEP using a single IMU in daily life. Also, some OEP sub-classes are possible to be recognized for further analysis.
format Preprint
id arxiv_https___arxiv_org_abs_2310_03512
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Otago Exercises Monitoring for Older Adults by a Single IMU and Hierarchical Machine Learning Models
Shang, Meng
Dedeyne, Lenore
Dupont, Jolan
Vercauteren, Laura
Amini, Nadjia
Lapauw, Laurence
Gielen, Evelien
Verschueren, Sabine
Varon, Carolina
De Raedt, Walter
Vanrumste, Bart
Machine Learning
Otago Exercise Program (OEP) is a rehabilitation program for older adults to improve frailty, sarcopenia, and balance. Accurate monitoring of patient involvement in OEP is challenging, as self-reports (diaries) are often unreliable. With the development of wearable sensors, Human Activity Recognition (HAR) systems using wearable sensors have revolutionized healthcare. However, their usage for OEP still shows limited performance. The objective of this study is to build an unobtrusive and accurate system to monitor OEP for older adults. Data was collected from older adults wearing a single waist-mounted Inertial Measurement Unit (IMU). Two datasets were collected, one in a laboratory setting, and one at the homes of the patients. A hierarchical system is proposed with two stages: 1) using a deep learning model to recognize whether the patients are performing OEP or activities of daily life (ADLs) using a 10-minute sliding window; 2) based on stage 1, using a 6-second sliding window to recognize the OEP sub-classes performed. The results showed that in stage 1, OEP could be recognized with window-wise f1-scores over 0.95 and Intersection-over-Union (IoU) f1-scores over 0.85 for both datasets. In stage 2, for the home scenario, four activities could be recognized with f1-scores over 0.8: ankle plantarflexors, abdominal muscles, knee bends, and sit-to-stand. The results showed the potential of monitoring the compliance of OEP using a single IMU in daily life. Also, some OEP sub-classes are possible to be recognized for further analysis.
title Otago Exercises Monitoring for Older Adults by a Single IMU and Hierarchical Machine Learning Models
topic Machine Learning
url https://arxiv.org/abs/2310.03512