Iterative Learning of Energy-Efficient Dynamic Walking Gaits

Abstract

Dynamic walking robots have the potential for efficient and lifelike locomotion, but computing efficient gaits and tracking them is difficult in the presence of under-modeling. Iterative Learning Control (ILC) is a method to learn the control signal to track a periodic reference over several attempts, augmenting a model with online data. Terminal ILC (TILC), a variant of ILC, allows other performance objectives to be addressed at the cost of ignoring parts of the reference. However, dynamic walking robot gaits are not necessarily periodic in time. In this paper, we adapt TILC to jointly optimize final foot placement and energy efficiency on dynamic walking robots by indexing by a phase variable instead of time, yielding “phase-indexed TILC” (θ - TILC). When implemented on a five-link walker in simulation, θ- TILC learns a more energy-efficient walking motion compared to traditional time-indexed TILC.