Title :
Simulation and optimization of basic movements in FES-driven paraplegics
Author :
Puri, Monica ; Wolpert, Seth
Author_Institution :
Dept. of Electr. & Comput. Eng., Maine Univ., Orono, ME, USA
Abstract :
In this study, a computer platform for investigating optimal trajectories of FES-induced motion was developed. Similar to a gait analysis program, this system interprets body segment lengths and joint angle trajectories for a subject undergoing an arbitrary movement, and displays that movement, along with a center of mass and time plot of the moment about the knee joint on-screen. Movements to be optimized in the near term are sit-to-stand transitions, stand-to-sit transitions, shifting weight side-to-side while seated, and single steps over small architectural barriers. These motions will be optimized for stability, efficiency, safety, and stress, as applied to a T-10 paraplegic human subject undergoing FNS of ten motor nerves in each leg. The program was demonstrated to work for sit-to-stand and stand-to-sit motions, and is now used to optimize those transitions
Keywords :
bioelectric phenomena; biomechanics; digital simulation; medical computing; muscle; neurophysiology; optimisation; orthotics; FES-driven paraplegics; T-10 paraplegic human subject; arbitrary movement; basic movements optimization; basic movements simulation; body segment lengths; center of mass; computer platform; gait analysis program; joint angle trajectories; knee joint moment; motor nerves; optimal trajectories; shifting weight side-to-side; single steps; sit-to-stand transitions; small architectural barriers; stand-to-sit transitions; Computational modeling; Electrodes; Energy efficiency; Implants; Knee; Legged locomotion; Motion analysis; Safety; Stability; Stress;
Conference_Titel :
Bioengineering Conference, 1995., Proceedings of the 1995 IEEE 21st Annual Northeast
Conference_Location :
Bar Harbor, ME
Print_ISBN :
0-7803-2692-X
DOI :
10.1109/NEBC.1995.513721
