Extended Application of Inertial Measurement Units in Biomechanics: From Activity Recognition to Force Estimation

Overview

Journal Sensors (Basel)

Publisher MDPI

Specialty Biotechnology

Date 2023 May 13

PMID 37177436

Authors

Wenqi Liang

Fanjie Wang

Ao Fan

Wenrui Zhao

Wei Yao

Pengfei Yang

Affiliations

Soon will be listed here.

Abstract

Abnormal posture or movement is generally the indicator of musculoskeletal injuries or diseases. Mechanical forces dominate the injury and recovery processes of musculoskeletal tissue. Using kinematic data collected from wearable sensors (notably IMUs) as input, activity recognition and musculoskeletal force (typically represented by ground reaction force, joint force/torque, and muscle activity/force) estimation approaches based on machine learning models have demonstrated their superior accuracy. The purpose of the present study is to summarize recent achievements in the application of IMUs in biomechanics, with an emphasis on activity recognition and mechanical force estimation. The methodology adopted in such applications, including data pre-processing, noise suppression, classification models, force/torque estimation models, and the corresponding application effects, are reviewed. The extent of the applications of IMUs in daily activity assessment, posture assessment, disease diagnosis, rehabilitation, and exoskeleton control strategy development are illustrated and discussed. More importantly, the technical feasibility and application opportunities of musculoskeletal force prediction using IMU-based wearable devices are indicated and highlighted. With the development and application of novel adaptive networks and deep learning models, the accurate estimation of musculoskeletal forces can become a research field worthy of further attention.

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References

Faber H, van Soest A, Kistemaker D . Inverse dynamics of mechanical multibody systems: An improved algorithm that ensures consistency between kinematics and external forces. PLoS One. 2018; 13(9):e0204575. PMC: 6161892. DOI: 10.1371/journal.pone.0204575. View

Eyobu O, Han D . Feature Representation and Data Augmentation for Human Activity Classification Based on Wearable IMU Sensor Data Using a Deep LSTM Neural Network. Sensors (Basel). 2018; 18(9). PMC: 6165524. DOI: 10.3390/s18092892. View

Camargo J, Ramanathan A, Flanagan W, Young A . A comprehensive, open-source dataset of lower limb biomechanics in multiple conditions of stairs, ramps, and level-ground ambulation and transitions. J Biomech. 2021; 119:110320. DOI: 10.1016/j.jbiomech.2021.110320. View

Ordonez F, Roggen D . Deep Convolutional and LSTM Recurrent Neural Networks for Multimodal Wearable Activity Recognition. Sensors (Basel). 2016; 16(1). PMC: 4732148. DOI: 10.3390/s16010115. View

Alemayoh T, Lee J, Okamoto S . New Sensor Data Structuring for Deeper Feature Extraction in Human Activity Recognition. Sensors (Basel). 2021; 21(8). PMC: 8073736. DOI: 10.3390/s21082814. View

Alcantara R, Edwards W, Millet G, Grabowski A . Predicting continuous ground reaction forces from accelerometers during uphill and downhill running: a recurrent neural network solution. PeerJ. 2022; 10:e12752. PMC: 8740512. DOI: 10.7717/peerj.12752. View

Stetter B, Ringhof S, Krafft F, Sell S, Stein T . Estimation of Knee Joint Forces in Sport Movements Using Wearable Sensors and Machine Learning. Sensors (Basel). 2019; 19(17). PMC: 6749227. DOI: 10.3390/s19173690. View

Durandau G, Farina D, Sartori M . Robust Real-Time Musculoskeletal Modeling Driven by Electromyograms. IEEE Trans Biomed Eng. 2017; 65(3):556-564. DOI: 10.1109/TBME.2017.2704085. View

Kutzner I, Heinlein B, Graichen F, Bender A, Rohlmann A, Halder A . Loading of the knee joint during activities of daily living measured in vivo in five subjects. J Biomech. 2010; 43(11):2164-73. DOI: 10.1016/j.jbiomech.2010.03.046. View

10.

Yang W, Zhang J, Zhang S, Yang C . Lower Limb Exoskeleton Gait Planning Based on Crutch and Human-Machine Foot Combined Center of Pressure. Sensors (Basel). 2020; 20(24). PMC: 7766720. DOI: 10.3390/s20247216. View

11.

Clemente F, Akyildiz Z, Pino-Ortega J, Rico-Gonzalez M . Validity and Reliability of the Inertial Measurement Unit for Barbell Velocity Assessments: A Systematic Review. Sensors (Basel). 2021; 21(7). PMC: 8038306. DOI: 10.3390/s21072511. View

12.

Derie R, Robberechts P, Van den Berghe P, Gerlo J, Clercq D, Segers V . Tibial Acceleration-Based Prediction of Maximal Vertical Loading Rate During Overground Running: A Machine Learning Approach. Front Bioeng Biotechnol. 2020; 8:33. PMC: 7010603. DOI: 10.3389/fbioe.2020.00033. View

13.

Johnson W, Mian A, Robinson M, Verheul J, Lloyd D, Alderson J . Multidimensional Ground Reaction Forces and Moments From Wearable Sensor Accelerations via Deep Learning. IEEE Trans Biomed Eng. 2020; 68(1):289-297. DOI: 10.1109/TBME.2020.3006158. View

14.

Vargas-Valencia L, Elias A, Rocon E, Bastos-Filho T, Frizera A . An IMU-to-Body Alignment Method Applied to Human Gait Analysis. Sensors (Basel). 2016; 16(12). PMC: 5191070. DOI: 10.3390/s16122090. View

15.

Ancillao A, Tedesco S, Barton J, OFlynn B . Indirect Measurement of Ground Reaction Forces and Moments by Means of Wearable Inertial Sensors: A Systematic Review. Sensors (Basel). 2018; 18(8). PMC: 6111315. DOI: 10.3390/s18082564. View

16.

Stergiou N, Giakas G, Byrne J, Pomeroy V . Frequency domain characteristics of ground reaction forces during walking of young and elderly females. Clin Biomech (Bristol). 2002; 17(8):615-7. DOI: 10.1016/s0268-0033(02)00072-4. View

17.

Yurtman A, Barshan B . Activity Recognition Invariant to Sensor Orientation with Wearable Motion Sensors. Sensors (Basel). 2017; 17(8). PMC: 5579846. DOI: 10.3390/s17081838. View

18.

Pei L, Guinness R, Chen R, Liu J, Kuusniemi H, Chen Y . Human behavior cognition using smartphone sensors. Sensors (Basel). 2013; 13(2):1402-24. PMC: 3649388. DOI: 10.3390/s130201402. View

19.

Guo Y, Storm F, Zhao Y, Billings S, Pavic A, Mazza C . A New Proxy Measurement Algorithm with Application to the Estimation of Vertical Ground Reaction Forces Using Wearable Sensors. Sensors (Basel). 2017; 17(10). PMC: 5677265. DOI: 10.3390/s17102181. View

20.

Iosa M, Picerno P, Paolucci S, Morone G . Wearable inertial sensors for human movement analysis. Expert Rev Med Devices. 2016; 13(7):641-59. DOI: 10.1080/17434440.2016.1198694. View