TY - GEN
T1 - A comparison of footfall detection algorithms from walker mounted sensors data
AU - Seedat, Nabeel
AU - Beder, David
AU - Aharonson, Vered
AU - Dubowsky, Steven
N1 - Publisher Copyright:
© 2018 IEEE.
PY - 2018/6/20
Y1 - 2018/6/20
N2 - Footfall detection is an essential element in the quantification of human walking patterns. It is often used for gait analysis and for the assessment of gait disorders. Most current methods are either subjective and rely on human observation, or are performed using complex and expensive equipment, and both solution types are primarily used in laboratory settings. We address the aforementioned systems limitations using low cost sensors mounted on an instrumented walker. The sensors namely distance encoders, force sensors and an accelerometer, acquire kinematic signals. We propose a new footfall extraction algorithm based on the accelerometer z-axis signal and compare it to a previously proposed algorithm which was based on force sensors. Both algorithms make use of Empirical Mode Decom, position (EMD) in order to decompose, filter and reconstruct the respective kinematic signals. Subsequently, threshold based peak detection is applied to estimate potential footfalls. The algorithms results are validated using video of subjects carrying out walking tests. The best detection accuracy for both algorithms was achieved when reconstructing the decomposed signal from the 3rd Intrinsic Mode Function level of the EMD signal. The algorithm using the accelerometer signal demonstrated greater detection accuracy of 86%, whereas the force sensor algorithm yielded an accuracy of 69%. The results imply that combination of the simple low cost accelerometer mounted on a walker and the new footfall detection algorithm, may provide a useful and affordable method of gait analysis.
AB - Footfall detection is an essential element in the quantification of human walking patterns. It is often used for gait analysis and for the assessment of gait disorders. Most current methods are either subjective and rely on human observation, or are performed using complex and expensive equipment, and both solution types are primarily used in laboratory settings. We address the aforementioned systems limitations using low cost sensors mounted on an instrumented walker. The sensors namely distance encoders, force sensors and an accelerometer, acquire kinematic signals. We propose a new footfall extraction algorithm based on the accelerometer z-axis signal and compare it to a previously proposed algorithm which was based on force sensors. Both algorithms make use of Empirical Mode Decom, position (EMD) in order to decompose, filter and reconstruct the respective kinematic signals. Subsequently, threshold based peak detection is applied to estimate potential footfalls. The algorithms results are validated using video of subjects carrying out walking tests. The best detection accuracy for both algorithms was achieved when reconstructing the decomposed signal from the 3rd Intrinsic Mode Function level of the EMD signal. The algorithm using the accelerometer signal demonstrated greater detection accuracy of 86%, whereas the force sensor algorithm yielded an accuracy of 69%. The results imply that combination of the simple low cost accelerometer mounted on a walker and the new footfall detection algorithm, may provide a useful and affordable method of gait analysis.
KW - Accelerometer
KW - Empirical Mode Decomposition
KW - Footfalls
KW - Gait
KW - Instrumented Walker
KW - signal processing
UR - https://www.scopus.com/pages/publications/85050226628
U2 - 10.1109/EBBT.2018.8391456
DO - 10.1109/EBBT.2018.8391456
M3 - Conference contribution
AN - SCOPUS:85050226628
T3 - 2018 Electric Electronics, Computer Science, Biomedical Engineerings' Meeting, EBBT 2018
SP - 1
EP - 4
BT - 2018 Electric Electronics, Computer Science, Biomedical Engineerings' Meeting, EBBT 2018
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 4th Electric Electronics, Computer Science, Biomedical Engineerings' Meeting, EBBT 2018
Y2 - 18 April 2018 through 19 April 2018
ER -