Title :
Trajectory planning for antagonistic non-linearly quantized SMA actuator arrays based on evolutionary optimization
Author :
Katoch, Rohan ; Ueda, Jun
Author_Institution :
Woodruff Sch. of Mech. Eng., Georgia Inst. of Technol., Atlanta, GA, USA
Abstract :
This paper presents an evolutionary optimization approach to the control of antagonistic shape memory alloy (SMA) actuator arrays. The actuator and control architectures are inspired by the neuromuscular system, which achieves smooth and accurate movements despite nonlinearities and uncertainties in control and estimation. SMA actuators produce contractile forces and have a high power-density, but exhibit nonlinearity and significant hysteresis in their thermo-mechanical behavior. A floating-point quantization (FPQ) schema is used to determine a non-uniform array distribution, resulting in motor variability similar to that observed in humans. Actuator arrays are used in an antagonistic configuration for joint control of a planar link. An evolutionary optimization approach is used to determine the optimal control inputs for point-to-point trajectories.
Keywords :
actuators; control nonlinearities; evolutionary computation; nonlinear control systems; optimal control; path planning; shape memory effects; uncertain systems; FPQ schema; antagonistic nonlinearly quantized SMA actuator arrays; antagonistic shape memory alloy actuator arrays; contractile forces; control architectures; control nonlinearities; control uncertainties; evolutionary optimization approach; floating-point quantization schema; motor variability; neuromuscular system; optimal control inputs; point-to-point trajectories; power density; thermo-mechanical behavior; trajectory planning; Actuators; Aerospace electronics; Force; Hysteresis motors; Muscles; Optimization; Recruitment;
Conference_Titel :
American Control Conference (ACC), 2015
Conference_Location :
Chicago, IL
Print_ISBN :
978-1-4799-8685-9
DOI :
10.1109/ACC.2015.7171131
