12 research outputs found
Identification of electrically stimulated quadriceps - lower leg dynamics - the use of accelerometers for estimating knee joint acceleration and quadriceps torque
Knee joiiit acceleration aid quadriceps torque call be estbated from the signals of two tangentially yliiced accelerometers. This euables the ideutificatiou of qundriceps dynamics, loaded with a freely swiugiug lower leg, during electrical stimulation
Identification of quadriceps-shank dynamics using randomized interpulse interval stimulation
Model structures for artificially stimulated paralyzed muscle-limb system dynamics were developed and experimentally evaluated in paraplegic patients. The examined system consisted of the quadriceps, electrically stimulated using surface electrodes, and a freely swinging shank. The interpulse interval of the stimulation sequence was randomized to obtain persistent system excitation. The outputs of the system were the angular position, velocity, and acceleration, measured by externally mounted sensors. The authors especially report on model identification of the active quadriceps dynamics and the angle prediction performance of the total quadriceps-shank model. Second-order modeling of the twitch dynamics with delay did not significantly improve the prediction results in comparison to a zero-order model with delay (¿=0.05). Nonlinear torque-angle and torque-angular velocity relations in combination with a zero-order model (with delay) only slightly improved the prediction results for large prediction intervals (¿=0.05). The delay between stimulation input and resulting knee joint acceleration appeared to be joint angle dependent and was estimated to be largest in the knee angle range near knee extension, i.e., when quadriceps muscle is shortes