Doppler Radar for the Extraction of Biomechanical Parameters in Gait Analysis
Overview
Medical Informatics
Affiliations
The applicability of Doppler radar for gait analysis is investigated by quantitatively comparing the measured biomechanical parameters to those obtained using motion capturing and ground reaction forces. Nineteen individuals walked on a treadmill at two different speeds, where a radar system was positioned in front of or behind the subject. The right knee angle was confined by an adjustable orthosis in five different degrees. Eleven gait parameters are extracted from radar micro-Doppler signatures. Here, new methods for obtaining the velocities of individual lower limb joints are proposed. Further, a new method to extract individual leg flight times from radar data is introduced. Based on radar data, five spatiotemporal parameters related to rhythm and pace could reliably be extracted. Further, for most of the considered conditions, three kinematic parameters could accurately be measured. The radar-based stance and flight time measurements rely on the correct detection of the time instant of maximal knee velocity during the gait cycle. This time instant is reliably detected when the radar has a back view, but is underestimated when the radar is positioned in front of the subject. The results validate the applicability of Doppler radar to accurately measure a variety of medically relevant gait parameters. Radar has the potential to unobtrusively diagnose changes in gait, e.g., to design training in prevention and rehabilitation. As contact-less and privacy-preserving sensor, radar presents a viable technology to supplement existing gait analysis tools for long-term in-home examinations.
A Review and Tutorial on Machine Learning-Enabled Radar-Based Biomedical Monitoring.
Krauss D, Engel L, Ott T, Braunig J, Richer R, Gambietz M IEEE Open J Eng Med Biol. 2024; 5:680-699.
PMID: 39193041 PMC: 11348957. DOI: 10.1109/OJEMB.2024.3397208.
Overview of Radar-Based Gait Parameter Estimation Techniques for Fall Risk Assessment.
Gurbuz S, Rahman M, Bassiri Z, Martelli D IEEE Open J Eng Med Biol. 2024; 5:735-749.
PMID: 39184960 PMC: 11342925. DOI: 10.1109/OJEMB.2024.3408078.
E-BDL: Enhanced Band-Dependent Learning Framework for Augmented Radar Sensing.
Cai F, Wu T, Lure F Sensors (Basel). 2024; 24(14).
PMID: 39066018 PMC: 11280770. DOI: 10.3390/s24144620.
Extraction and Validation of Biomechanical Gait Parameters with Contactless FMCW Radar.
Wang L, Ni Z, Huang B Sensors (Basel). 2024; 24(13).
PMID: 39000963 PMC: 11244313. DOI: 10.3390/s24134184.
Pattern analysis using lower body human walking data to identify the gaitprint.
Wiles T, Kim S, Stergiou N, Likens A Comput Struct Biotechnol J. 2024; 24:281-291.
PMID: 38644928 PMC: 11033172. DOI: 10.1016/j.csbj.2024.04.017.