Mobile Stride Length Estimation With Deep Convolutional Neural Networks

Objective: Accurate estimation of spatial gait characteristics is critical to assess motor impairments resulting from neurological or musculoskeletal disease. Currently, however, methodological constraints limit clinical applicability of state-of-the-art double integration approaches to gait pattern...

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Bibliographic Details
Published in:IEEE journal of biomedical and health informatics 2018-03, Vol.22 (2), p.354-362
Main Authors: Hannink, Julius, Kautz, Thomas, Pasluosta, Cristian F., Barth, Jens, Schulein, Samuel, Gassmann, Karl-Gunter, Klucken, Jochen, Eskofier, Bjoern M.
Format: Article
Language:English
Subjects:
Artificial neural networks
Benchmarks
Biological system modeling
convolutional neural networks
Databases, Factual
Datasets
Deep Learning
Disease control
Diseases
Estimation
Gait
Gait - physiology
Humans
Inertial sensing devices
Integration
Magnetic domains
Mathematical model
Mobile communication
mobile gait analysis
Models, Biological
Musculoskeletal diseases
Neural networks
Neural Networks (Computer)
Neurological diseases
regression
Regression Analysis
Retraining
Senior citizens
Signal Processing, Computer-Assisted
State of the art
stride length
Walking - physiology
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Description
Summary:Objective: Accurate estimation of spatial gait characteristics is critical to assess motor impairments resulting from neurological or musculoskeletal disease. Currently, however, methodological constraints limit clinical applicability of state-of-the-art double integration approaches to gait patterns with a clear zero-velocity phase. Methods: We describe a novel approach to stride length estimation that uses deep convolutional neural networks to map stride-specific inertial sensor data to the resulting stride length. The model is trained on a publicly available and clinically relevant benchmark dataset consisting of 1220 strides from 101 geriatric patients. Evaluation is done in a tenfold cross validation and for three different stride definitions. Results: Even though best results are achieved with strides defined from midstance to midstance with average accuracy and precision of 0.01 ± 5.37 cm, performance does not strongly depend on stride definition. The achieved precision outperforms state-of-the-art methods evaluated on the same benchmark dataset by 3.0 cm (36%). Conclusion: Due to the independence of stride definition, the proposed method is not subject to the methodological constrains that limit applicability of state-of-the-art double integration methods. Furthermore, it was possible to improve precision on the benchmark dataset. Significance: With more precise mobile stride length estimation, new insights to the progression of neurological disease or early indications might be gained. Due to the independence of stride definition, previously uncharted diseases in terms of mobile gait analysis can now be investigated by retraining and applying the proposed method.
ISSN:2168-2194
2168-2208
DOI:10.1109/JBHI.2017.2679486