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16 results on '"Seifert, Ann-Kathrin"'

1. Doppler Radar for the Extraction of Biomechanical Parameters in Gait Analysis

Author

Seifert, Ann-Kathrin, Grimmer, Martin, and Zoubir, Abdelhak M.

Subjects
Electrical Engineering and Systems Science - Signal Processing
Abstract

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., Comment: 13 pages, 9 figures, 2 tables, accepted for publication in the IEEE Journal of Biomedical and Health Informatics (J-BHI)

Published
2020

2. Detection of Gait Asymmetry Using Indoor Doppler Radar

Author

Seifert, Ann-Kathrin, Zoubir, Abdelhak M., and Amin, Moeness G.

Subjects
Electrical Engineering and Systems Science - Signal Processing
Abstract

Doppler radar systems enable unobtrusive and privacy-preserving long-term monitoring of human motions indoors. In particular, a person's gait can provide important information about their state of health. Utilizing micro-Doppler signatures, we show that radar is capable of detecting small differences between the step motions of the two legs, which results in asymmetric gait. Image-based and physical features are extracted from the radar return signals of several individuals, including four persons with different diagnosed gait disorders. It is shown that gait asymmetry is correctly detected with high probability, irrespective of the underlying pathology, for at least one motion direction., Comment: 6 pages, 5 figures, 4 tables; accepted at the IEEE Radar Conference 2019, Boston, MA, USA

Published
2019

3. Toward Unobtrusive In-home Gait Analysis Based on Radar Micro-Doppler Signatures

Author

Seifert, Ann-Kathrin, Amin, Moeness G., and Zoubir, Abdelhak M.

Subjects
Electrical Engineering and Systems Science - Signal Processing
Abstract

Objective: In this paper, we demonstrate the applicability of radar for gait classification with application to home security, medical diagnosis, rehabilitation and assisted living. Aiming at identifying changes in gait patterns based on radar micro-Doppler signatures, this work is concerned with solving the intra motion category classification problem of gait recognition. Methods: New gait classification approaches utilizing physical features, subspace features and sum-of-harmonics modeling are presented and their performances are evaluated using experimental K-band radar data of four test subjects. Five different gait classes are considered for each person, including normal, pathological and assisted walks. Results: The proposed approaches are shown to outperform existing methods for radar-based gait recognition which utilize physical features from the cadence-velocity data representation domain as in this paper. The analyzed gait classes are correctly identified with an average accuracy of 93.8%, where a classification rate of 98.5% is achieved for a single gait class. When applied to new data of another individual a classification accuracy on the order of 80% can be expected. Conclusion: Radar micro-Doppler signatures and their Fourier transforms are well suited to capture changes in gait. Five different walking styles are recognized with high accuracy. Significance: Radar-based sensing of human gait is an emerging technology with multi-faceted applications in security and health care industries. We show that radar, as a contact-less sensing technology, can supplement existing gait diagnostic tools with respect to long-term monitoring and reproducibility of the examinations., Comment: 11 pages, 6 figures

Published
2018
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5. Signal Processing for Radar-Based Gait Analysis

Author

Seifert, Ann-Kathrin

Abstract

In this PhD thesis signal processing methods are developed for radar-based gait analysis. Analyzing the backscattered radio frequency waves from a moving non-rigid target in the time-frequency domain, reveals so-called micro-Doppler signatures. In the case of a walking person, these micro-Doppler signatures relate to gait kinematics by capturing velocity, acceleration, and rotation of individual body parts. Hence, they can be exploited for general gait classification and basic gait analysis. In the area of radar-based gait classification, a signal processing framework is developed to discriminate between five walking styles, including abnormal and cane-assisted gait. Toward this end, different joint-variable signal representations, including the spectrogram and the so-called cadence-velocity diagram, are adapted. These representations are used to identify physically interpretable features, and as input to automatic feature learning using principal component analysis. The thus obtained feature sets are evaluated and compared in terms of their corresponding classification performance. Additionally, a gait asymmetry detector is presented to identify differences between the left and right leg's motions from radar micro-Doppler signatures. The evaluation of the developed methods is based on realistic experimental radar data of 10 able-bodied individuals, and four persons with diagnosed gait disorders. Toward radar-based gait analysis, the thesis demonstrates the use of Doppler radar for measuring a set of medically relevant gait parameters, including stride time and maximal lower limb velocities. Here, a new method is presented for measuring the flight time through a radar device. In total, 11 biomechanical gait parameters are extracted and qualitatively and quantitatively assessed by using marker-based motion capture data. Further, parametric models for the radial velocities of the lower limbs during walking are developed. These models are then employed to estimate lower limb angular kinematics, namely, the hip and knee angle, from radar micro-Doppler step signatures. The developed methods are evaluated based on experimental data of 19 able-bodied test persons walking on a treadmill. Here, one of the knees was systematically restricted through an adjustable orthosis to simulate different degrees of gait abnormality. The results of this thesis demonstrate the capabilities of radar to capture differences in gait patterns. In particular, the developed signal processing frameworks allow for discriminating between different walking styles and the measurement of medically relevant gait parameters based on radar backscatterings. Thus, it is shown that radio frequency sensing is a viable technology for unobtrusive in-home gait analysis. As such, this thesis contributes to the growing field of radar for indoor human monitoring with application to, e.g., telemedicine and assisted living.

Published
2020

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