ED-FNN: A New Deep Learning Algorithm to Detect Percentage of the Gait Cycle for Powered Prostheses

ED-FNN: A New Deep Learning Algorithm to Detect Percentage of the Gait Cycle for Powered Prostheses

Throughout the last decade, a whole new generation of powered transtibial prostheses and exoskeletons has been developed. However, these technologies are limited by a gait phase detection which controls the wearable device as a function of the activities of the wearer. Consequently, gait phase detec...

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Main Authors: Huong Thi Thu Vu, Felipe Gomez, Pierre Cherelle, Dirk Lefeber, Ann Nowé, Bram Vanderborght
Format: Article
Language:English
Published: MDPI AG 2018-07-01
Series:Sensors
Subjects:
gait phase prediction
gait event detection
lower limb prosthesis
exoskeleton
gait recognition
Online Access:http://www.mdpi.com/1424-8220/18/7/2389
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spelling doaj-fc528f51e7ad4cf08dc8c12a1cd182a32020-11-24T23:54:09ZengMDPI AGSensors1424-82202018-07-01187238910.3390/s18072389s18072389ED-FNN: A New Deep Learning Algorithm to Detect Percentage of the Gait Cycle for Powered ProsthesesHuong Thi Thu Vu0Felipe Gomez1Pierre Cherelle2Dirk Lefeber3Ann Nowé4Bram Vanderborght5Robotics & MultiBody Mechanics Research Group (R& MM) and Artificial Intelligence Lab, Vrije Universiteit Brussel and Flanders Make; Pleinlaan 2, 1050 Brussel, BelgiumRobotics & MultiBody Mechanics Research Group (R& MM) and Artificial Intelligence Lab, Vrije Universiteit Brussel and Flanders Make; Pleinlaan 2, 1050 Brussel, BelgiumRobotics & MultiBody Mechanics Research Group (R& MM) and Artificial Intelligence Lab, Vrije Universiteit Brussel and Flanders Make; Pleinlaan 2, 1050 Brussel, BelgiumRobotics & MultiBody Mechanics Research Group (R& MM) and Artificial Intelligence Lab, Vrije Universiteit Brussel and Flanders Make; Pleinlaan 2, 1050 Brussel, BelgiumRobotics & MultiBody Mechanics Research Group (R& MM) and Artificial Intelligence Lab, Vrije Universiteit Brussel and Flanders Make; Pleinlaan 2, 1050 Brussel, BelgiumRobotics & MultiBody Mechanics Research Group (R& MM) and Artificial Intelligence Lab, Vrije Universiteit Brussel and Flanders Make; Pleinlaan 2, 1050 Brussel, BelgiumThroughout the last decade, a whole new generation of powered transtibial prostheses and exoskeletons has been developed. However, these technologies are limited by a gait phase detection which controls the wearable device as a function of the activities of the wearer. Consequently, gait phase detection is considered to be of great importance, as achieving high detection accuracy will produce a more precise, stable, and safe rehabilitation device. In this paper, we propose a novel gait percent detection algorithm that can predict a full gait cycle discretised within a 1% interval. We called this algorithm an exponentially delayed fully connected neural network (ED-FNN). A dataset was obtained from seven healthy subjects that performed daily walking activities on the flat ground and a 15-degree slope. The signals were taken from only one inertial measurement unit (IMU) attached to the lower shank. The dataset was divided into training and validation datasets for every subject, and the mean square error (MSE) error between the model prediction and the real percentage of the gait was computed. An average MSE of 0.00522 was obtained for every subject in both training and validation sets, and an average MSE of 0.006 for the training set and 0.0116 for the validation set was obtained when combining all subjects’ signals together. Although our experiments were conducted in an offline setting, due to the forecasting capabilities of the ED-FNN, our system provides an opportunity to eliminate detection delays for real-time applications.http://www.mdpi.com/1424-8220/18/7/2389gait phase predictiongait event detectionlower limb prosthesisexoskeletongait recognition
collection DOAJ
language English
format Article
sources DOAJ
author Huong Thi Thu Vu
Felipe Gomez
Pierre Cherelle
Dirk Lefeber
Ann Nowé
Bram Vanderborght
spellingShingle Huong Thi Thu Vu
Felipe Gomez
Pierre Cherelle
Dirk Lefeber
Ann Nowé
Bram Vanderborght
ED-FNN: A New Deep Learning Algorithm to Detect Percentage of the Gait Cycle for Powered Prostheses
Sensors
gait phase prediction
gait event detection
lower limb prosthesis
exoskeleton
gait recognition
author_facet Huong Thi Thu Vu
Felipe Gomez
Pierre Cherelle
Dirk Lefeber
Ann Nowé
Bram Vanderborght
author_sort Huong Thi Thu Vu
title ED-FNN: A New Deep Learning Algorithm to Detect Percentage of the Gait Cycle for Powered Prostheses
title_short ED-FNN: A New Deep Learning Algorithm to Detect Percentage of the Gait Cycle for Powered Prostheses
title_full ED-FNN: A New Deep Learning Algorithm to Detect Percentage of the Gait Cycle for Powered Prostheses
title_fullStr ED-FNN: A New Deep Learning Algorithm to Detect Percentage of the Gait Cycle for Powered Prostheses
title_full_unstemmed ED-FNN: A New Deep Learning Algorithm to Detect Percentage of the Gait Cycle for Powered Prostheses
title_sort ed-fnn: a new deep learning algorithm to detect percentage of the gait cycle for powered prostheses
publisher MDPI AG
series Sensors
issn 1424-8220
publishDate 2018-07-01
description Throughout the last decade, a whole new generation of powered transtibial prostheses and exoskeletons has been developed. However, these technologies are limited by a gait phase detection which controls the wearable device as a function of the activities of the wearer. Consequently, gait phase detection is considered to be of great importance, as achieving high detection accuracy will produce a more precise, stable, and safe rehabilitation device. In this paper, we propose a novel gait percent detection algorithm that can predict a full gait cycle discretised within a 1% interval. We called this algorithm an exponentially delayed fully connected neural network (ED-FNN). A dataset was obtained from seven healthy subjects that performed daily walking activities on the flat ground and a 15-degree slope. The signals were taken from only one inertial measurement unit (IMU) attached to the lower shank. The dataset was divided into training and validation datasets for every subject, and the mean square error (MSE) error between the model prediction and the real percentage of the gait was computed. An average MSE of 0.00522 was obtained for every subject in both training and validation sets, and an average MSE of 0.006 for the training set and 0.0116 for the validation set was obtained when combining all subjects’ signals together. Although our experiments were conducted in an offline setting, due to the forecasting capabilities of the ED-FNN, our system provides an opportunity to eliminate detection delays for real-time applications.
topic gait phase prediction
gait event detection
lower limb prosthesis
exoskeleton
gait recognition
url http://www.mdpi.com/1424-8220/18/7/2389
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