Real-Time Activity Recognition With Instantaneous Characteristic Features of Thigh Kinematics

Overview

Journal IEEE Trans Neural Syst Rehabil Eng

Publisher IEEE

Specialties Biomedical Engineering
Rehabilitation Medicine

Date 2021 Aug 24

PMID 34428147

Citations 11

Authors

Shihao Cheng

Edgar Bolivar-Nieto

Robert D Gregg

Affiliations

Soon will be listed here.

Abstract

Current supervised learning or deep learning-based activity recognition classifiers can achieve high accuracy in recognizing locomotion activities. Most available techniques use a high-dimensional space of features, e.g., combinations of EMG, kinematics and kinetics, and transformations over those signals. The associated classification rules are therefore complex; the machine tries to understand the human, but the human does not understand the machine. This paper presents an activity recognition system that uses signals from a thigh-mounted IMU and a force sensitive resistor to classify transitions between sitting, walking, stair ascending, and stair descending. The system uses the thigh's orientation and velocity with foot contact information at specific moments within a given activity as the features to classify transitions to other activities. We call these Instantaneous Characteristic Features (ICFs). Because these ICFs are biomechanically intuitive, they are easy for the user to understand and thus control the activity transitions of wearable robots. We assessed our classification algorithm offline using an existing dataset with 10 able-bodied subjects and online with another 10 able-bodied subjects wearing a real-time system. The offline study analyzed the effect of subject-dependency and ramp inclinations. The real-time classification accuracy was evaluated before and after training the subjects on the ICFs. The real-time system achieved overall pre-subject-training and post-subject-training error rates of 0.59% ± 0.24% and 0.56% ± 0.20%, respectively. We also evaluated the feasibility of our ICFs for amputee ambulation by analyzing a public dataset with the open-source bionic leg. The simplicity of these classification rules demonstrates a new paradigm for activity recognition where the human can understand the machine and vice-versa.

Citing Articles

Lateral walking gait phase recognition for hip exoskeleton by denoising autoencoder-LSTM.

Luo M, Dong X, Yu H, Zhang M, Wu X, Kobsiriphat W Comput Struct Biotechnol J. 2025; 28:50-62.

PMID: 40026802 PMC: 11871487. DOI: 10.1016/j.csbj.2025.02.001.

Controlling Powered Prosthesis Kinematics Over Continuous Inter-Leg Transitions Between Walking and Stair Ascent/Descent.

Cheng S, Laubscher C, Gregg R IEEE Trans Neural Syst Rehabil Eng. 2024; 32:3891-3901.

PMID: 39446547 PMC: 11608573. DOI: 10.1109/TNSRE.2024.3485643.

Transfer Learning for Efficient Intent Prediction in Lower-Limb Prosthetics: A Strategy for Limited Datasets.

Le D, Cheng S, Gregg R, Ghaffari M IEEE Robot Autom Lett. 2024; 9(5):4321-4328.

PMID: 39081804 PMC: 11286256. DOI: 10.1109/lra.2024.3379800.

Swing-phase detection of locomotive mode transitions for smooth multi-functional robotic lower-limb prosthesis control.

Haque M, Islam M, Sazonov E, Shen X Front Robot AI. 2024; 11:1267072.

PMID: 38680622 PMC: 11045955. DOI: 10.3389/frobt.2024.1267072.

A SE-DenseNet-LSTM model for locomotion mode recognition in lower limb exoskeleton.

Tang J, Zhao L, Wu M, Jiang Z, Cao J, Bao X PeerJ Comput Sci. 2024; 10:e1881.

PMID: 38435551 PMC: 10909223. DOI: 10.7717/peerj-cs.1881.

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