Title :
Towards a dynamic actuator model for a hexapod robot
Author :
McMordie, Dave ; Prahacs, Chris ; Buehler, Martin
Author_Institution :
Ambulatory Robotics Lab., McGill Univ., Montreal, Que., Canada
Abstract :
We describe a model predicting the output torque of the battery-amplifier-actuator-gear combination used on the hexapod robot RHex, based on requested PWM (pulse width modulation) duty cycle to the amplifier, battery voltage, and motor speed. The model is broken into independent components, each experimentally validated: power source (battery), motor amplifier, motor and (planetary) gear. The resulting aggregate model shows <6% full scale RMS error in predicting output torque in the first quadrant of operation (positive torques). Understanding the key ingredients and the attainable accuracies of torque production models in our commonly used battery-amplifier-actuator-gear combinations is critical for mobile robots, in order to minimize sensing, and thus space, size, weight, power consumption, failure rate, and cost of mobile robots.
Keywords :
amplifiers; brushless DC motors; electric actuators; mobile robots; permanent magnet motors; power consumption; pulse width modulation; torque control; DC permanent magnet brush motor; PWM duty cycle; battery voltage; battery-amplifier-actuator-gear combination; dynamic actuator model; failure rate; full scale RMS error; hexapod robot; hexapod robot RHex; independent components; mobile robots; motor amplifier; motor speed; output torque; planetary gear; power consumption; pulse width modulation; space size; Actuators; Batteries; Dynamic voltage scaling; Mobile robots; Power amplifiers; Predictive models; Pulse amplifiers; Pulse width modulation; Space vector pulse width modulation; Torque;
Conference_Titel :
Robotics and Automation, 2003. Proceedings. ICRA '03. IEEE International Conference on
Print_ISBN :
0-7803-7736-2
DOI :
10.1109/ROBOT.2003.1241785
