Terrain Type Detection for Smart Equine Gait Analysis Systems Using Inertial Sensors and Machine Learning

J.I.M. Parmentier; Filipe M. Serra Bragança; Elin Hernlund; Berend Jan van der Zwaag

doi:10.1109/DCOSS-IoT58021.2023.00029

Terrain Type Detection for Smart Equine Gait Analysis Systems Using Inertial Sensors and Machine Learning

J.I.M. Parmentier^*, Filipe M. Serra Bragança, Elin Hernlund, Berend Jan van der Zwaag

^*Corresponding author for this work

Research output: Contribution to conference › Paper › peer-review

2 Citations (Scopus)

146 Downloads (Pure)

Abstract

Lameness, limping due to pain, is a significant welfare issue for horses. Veterinarians typically evaluate horses on two terrain types (hard and soft, e.g., asphalt and sand) that are known to affect the observed degree of lameness based on the origin/location of the pain. In the past years, whole-body inertial measurement units (IMU)-based gait analysis systems were developed to support diagnostics and monitor locomotion changes over time. Movement direction and gait (walk, trot) are automatically labeled, resulting in smart and easy-to-use systems. However, terrain types are not detected, leading to information loss. In this work, we explored terrain classification tasks with equine IMU data and machine and deep learning. Using the data of 111 horses equipped with IMU sensors (withers, pelvis, front, and hind limbs), we compared different features-based (FT) and time-series-based (TS) classifiers (train-test ratio: 0.7-0.3). In order to reduce the computational costs of the future system, we also evaluated the performance (F1 score) of the classifiers with different sampling frequencies (10 to 200Hz) and different IMU combinations (body and limbs). Our Convolutional Neural Network models accurately classified terrain types with only one IMU placed on the front limb. Downsampling the signals led to similar results, thus enabling real-time applications.

Original language	English
Pages	103-111
Number of pages	9
DOIs	https://doi.org/10.1109/DCOSS-IoT58021.2023.00029
Publication status	Published - 27 Sept 2023
Event	19th International Conference on Distributed Computing in Smart Systems and the Internet of Things, DCOSS-IoT 2023 - Paphos, Cyprus Duration: 19 Jun 2023 → 21 Jun 2023 Conference number: 19 https://dcoss.org/dcoss23/

Conference

Conference	19th International Conference on Distributed Computing in Smart Systems and the Internet of Things, DCOSS-IoT 2023
Abbreviated title	DCOSS-IoT 2023
Country/Territory	Cyprus
City	Paphos
Period	19/06/23 → 21/06/23
Internet address	https://dcoss.org/dcoss23/

Keywords

2023 OA procedure

Access to Document

10.1109/DCOSS-IoT58021.2023.00029

Terrain_Type_Detection_for_Smart_Equine_Gait_Analysis_Systems_Using_Inertial_Sensors_and_Machine_LearningFinal published version, 554 KBLicence: Taverne

Cite this

Parmentier, J. I. M., Serra Bragança, F. M., Hernlund, E., & van der Zwaag, B. J. (2023). Terrain Type Detection for Smart Equine Gait Analysis Systems Using Inertial Sensors and Machine Learning. 103-111. Paper presented at 19th International Conference on Distributed Computing in Smart Systems and the Internet of Things, DCOSS-IoT 2023, Paphos, Cyprus. https://doi.org/10.1109/DCOSS-IoT58021.2023.00029

@conference{7fd44f85b93f4784b9fc7621d03abe55,

title = "Terrain Type Detection for Smart Equine Gait Analysis Systems Using Inertial Sensors and Machine Learning",

abstract = "Lameness, limping due to pain, is a significant welfare issue for horses. Veterinarians typically evaluate horses on two terrain types (hard and soft, e.g., asphalt and sand) that are known to affect the observed degree of lameness based on the origin/location of the pain. In the past years, whole-body inertial measurement units (IMU)-based gait analysis systems were developed to support diagnostics and monitor locomotion changes over time. Movement direction and gait (walk, trot) are automatically labeled, resulting in smart and easy-to-use systems. However, terrain types are not detected, leading to information loss. In this work, we explored terrain classification tasks with equine IMU data and machine and deep learning. Using the data of 111 horses equipped with IMU sensors (withers, pelvis, front, and hind limbs), we compared different features-based (FT) and time-series-based (TS) classifiers (train-test ratio: 0.7-0.3). In order to reduce the computational costs of the future system, we also evaluated the performance (F1 score) of the classifiers with different sampling frequencies (10 to 200Hz) and different IMU combinations (body and limbs). Our Convolutional Neural Network models accurately classified terrain types with only one IMU placed on the front limb. Downsampling the signals led to similar results, thus enabling real-time applications.",

keywords = "2023 OA procedure",

author = "J.I.M. Parmentier and \{Serra Bragan{\c c}a\}, \{Filipe M.\} and Elin Hernlund and \{van der Zwaag\}, \{Berend Jan\}",

note = "Funding Information: The authors would like to thank the horses{\textquoteright} owners and caretakers that were involved in the different data collection as well as the differentcolleagues present for the data collections. This project was partly funded by the EFRO OP-Oost (project Paardensprong) and the Dutch Arthritis Society (Centre of Excellence Grant LLP22). The Animal Ethics Committee of Utrecht University issued ethical permissions for the different data collections when required. Publisher Copyright: {\textcopyright} 2023 IEEE.; 19th International Conference on Distributed Computing in Smart Systems and the Internet of Things, DCOSS-IoT 2023, DCOSS-IoT 2023 ; Conference date: 19-06-2023 Through 21-06-2023",

year = "2023",

month = sep,

day = "27",

doi = "10.1109/DCOSS-IoT58021.2023.00029",

language = "English",

pages = "103--111",

url = "https://dcoss.org/dcoss23/",

}

Parmentier, JIM, Serra Bragança, FM, Hernlund, E & van der Zwaag, BJ 2023, 'Terrain Type Detection for Smart Equine Gait Analysis Systems Using Inertial Sensors and Machine Learning', Paper presented at 19th International Conference on Distributed Computing in Smart Systems and the Internet of Things, DCOSS-IoT 2023, Paphos, Cyprus, 19/06/23 - 21/06/23 pp. 103-111. https://doi.org/10.1109/DCOSS-IoT58021.2023.00029

Terrain Type Detection for Smart Equine Gait Analysis Systems Using Inertial Sensors and Machine Learning. / Parmentier, J.I.M.; Serra Bragança, Filipe M.; Hernlund, Elin et al.
2023. 103-111 Paper presented at 19th International Conference on Distributed Computing in Smart Systems and the Internet of Things, DCOSS-IoT 2023, Paphos, Cyprus.

Research output: Contribution to conference › Paper › peer-review

TY - CONF

T1 - Terrain Type Detection for Smart Equine Gait Analysis Systems Using Inertial Sensors and Machine Learning

AU - Parmentier, J.I.M.

AU - Serra Bragança, Filipe M.

AU - Hernlund, Elin

AU - van der Zwaag, Berend Jan

N1 - Conference code: 19

PY - 2023/9/27

Y1 - 2023/9/27

N2 - Lameness, limping due to pain, is a significant welfare issue for horses. Veterinarians typically evaluate horses on two terrain types (hard and soft, e.g., asphalt and sand) that are known to affect the observed degree of lameness based on the origin/location of the pain. In the past years, whole-body inertial measurement units (IMU)-based gait analysis systems were developed to support diagnostics and monitor locomotion changes over time. Movement direction and gait (walk, trot) are automatically labeled, resulting in smart and easy-to-use systems. However, terrain types are not detected, leading to information loss. In this work, we explored terrain classification tasks with equine IMU data and machine and deep learning. Using the data of 111 horses equipped with IMU sensors (withers, pelvis, front, and hind limbs), we compared different features-based (FT) and time-series-based (TS) classifiers (train-test ratio: 0.7-0.3). In order to reduce the computational costs of the future system, we also evaluated the performance (F1 score) of the classifiers with different sampling frequencies (10 to 200Hz) and different IMU combinations (body and limbs). Our Convolutional Neural Network models accurately classified terrain types with only one IMU placed on the front limb. Downsampling the signals led to similar results, thus enabling real-time applications.

AB - Lameness, limping due to pain, is a significant welfare issue for horses. Veterinarians typically evaluate horses on two terrain types (hard and soft, e.g., asphalt and sand) that are known to affect the observed degree of lameness based on the origin/location of the pain. In the past years, whole-body inertial measurement units (IMU)-based gait analysis systems were developed to support diagnostics and monitor locomotion changes over time. Movement direction and gait (walk, trot) are automatically labeled, resulting in smart and easy-to-use systems. However, terrain types are not detected, leading to information loss. In this work, we explored terrain classification tasks with equine IMU data and machine and deep learning. Using the data of 111 horses equipped with IMU sensors (withers, pelvis, front, and hind limbs), we compared different features-based (FT) and time-series-based (TS) classifiers (train-test ratio: 0.7-0.3). In order to reduce the computational costs of the future system, we also evaluated the performance (F1 score) of the classifiers with different sampling frequencies (10 to 200Hz) and different IMU combinations (body and limbs). Our Convolutional Neural Network models accurately classified terrain types with only one IMU placed on the front limb. Downsampling the signals led to similar results, thus enabling real-time applications.

KW - 2023 OA procedure

U2 - 10.1109/DCOSS-IoT58021.2023.00029

DO - 10.1109/DCOSS-IoT58021.2023.00029

M3 - Paper

SP - 103

EP - 111

T2 - 19th International Conference on Distributed Computing in Smart Systems and the Internet of Things, DCOSS-IoT 2023

Y2 - 19 June 2023 through 21 June 2023

ER -

Terrain Type Detection for Smart Equine Gait Analysis Systems Using Inertial Sensors and Machine Learning

Abstract

Conference

Keywords

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