An Investigation on the Effect of Actuation Pattern on the Power Consumption of Legged Robots for Extraterrestrial Exploration

Abstract

Legged robots have great potential to be extraterrestrial exploration rovers of extraordinary versatility. Minimizing power consumption is of vital importance in the scenarios of extraterrestrial explorations. The actuation pattern, which refers to the combination of necessary actuators that output torque, has a significant influence on the power consumption of legged robots. This article seeks to investigate the effect of actuation patterns on the power consumption of legged robots that perform motion in a quasi-static manner. The power consumption model of legged robots considering actuation patterns is deduced. Based on that, the effect of the actuation pattern on mechanical power and heat power, which are the main power-loss terms, is investigated. The lowest power consumption under various conditions achieved by different actuation patterns is investigated. Simulation results show that the power consumption can be reduced by choosing the actuation pattern properly. Furthermore, the principles of selecting the optimal actuation pattern from the perspective of power consumption are summarized, which are expected to facilitate the minimal power consumption motion planning of legged robots.