Your search keyword '"Functional Elec- trical Stimulation"' showing total 2 results

1. Step Prediction During Perturbed Standing Using Center Of Pressure Measurements

Author

Milos R. Popovic, Kei Masani, and Xavier Tortolero

Subjects

Posture, Balance Control, Center of Pressure, Neuroprosthesis, Functional Elec- trical Stimulation, Functional Neuromuscular Stimulation, Chemical technology, TP1-1185

Abstract

The development of a sensor that can measure balance during quiet standing and predict stepping response in the event of perturbation has many clinically relevant applica- tions, including closed-loop control of a neuroprothesis for standing. This study investigated the feasibility of an algorithm that can predict in real-time when an able-bodied individual who is quietly standing will have to make a step to compensate for an external perturbation. Anterior and posterior perturbations were performed on 16 able-bodied subjects using a pul- ley system with a dropped weight. A linear relationship was found between the peak center of pressure (COP) velocity and the peak COP displacement caused by the perturbation. This result suggests that one can predict when a person will have to make a step based on COP velocity measurements alone. Another important feature of this finding is that the peak COP velocity occurs considerably before the peak COP displacement. As a result, one can predict if a subject will have to make a step in response to a perturbation sufficiently ahead of the time when the subject is actually forced to make the step. The proposed instability detection algorithm will be implemented in a sensor system using insole sheets in shoes with minitur- ized pressure sensors by which the COPv can be continuously measured. The sensor system will be integrated in a closed-loop feedback system with a neuroprosthesis for standing in the near future.

Published

2007

2. Step prediction during perturbed standing using center of pressure measurements

Author

Kei Masani, Xavier Tortolero, and Milos R. Popovic

Subjects

Engineering, 0206 medical engineering, Posture, Perturbation (astronomy), 02 engineering and technology, lcsh:Chemical technology, Biochemistry, Instability, Analytical Chemistry, 03 medical and health sciences, 0302 clinical medicine, Balance Control, Center of pressure (terrestrial locomotion), Control theory, Functional Neuromuscular Stimulation, lcsh:TP1-1185, Electrical and Electronic Engineering, Instrumentation, Simulation, Sensor system, Full Paper, Functional Electrical Stimulation, business.industry, 020601 biomedical engineering, Pressure sensor, Atomic and Molecular Physics, and Optics, Linear relationship, Neuroprosthesis, Center of Pressure, Functional Elec- trical Stimulation, business, 030217 neurology & neurosurgery, Quiet standing

Abstract

The development of a sensor that can measure balance during quiet standing and predict stepping response in the event of perturbation has many clinically relevant applica- tions, including closed-loop control of a neuroprothesis for standing. This study investigated the feasibility of an algorithm that can predict in real-time when an able-bodied individual who is quietly standing will have to make a step to compensate for an external perturbation. Anterior and posterior perturbations were performed on 16 able-bodied subjects using a pul- ley system with a dropped weight. A linear relationship was found between the peak center of pressure (COP) velocity and the peak COP displacement caused by the perturbation. This result suggests that one can predict when a person will have to make a step based on COP velocity measurements alone. Another important feature of this finding is that the peak COP velocity occurs considerably before the peak COP displacement. As a result, one can predict if a subject will have to make a step in response to a perturbation sufficiently ahead of the time when the subject is actually forced to make the step. The proposed instability detection algorithm will be implemented in a sensor system using insole sheets in shoes with minitur- ized pressure sensors by which the COPv can be continuously measured. The sensor system will be integrated in a closed-loop feedback system with a neuroprosthesis for standing in the near future.