Skill memory in biped locomotion: using perceptual information to predict task outcome

Robots must be able to adapt their motor behavior to unexpected situations in order to safely move among humans. A necessary step is to be able to predict failures, which result in behavior abnormalities and may cause irrecoverable damage to the robot and its surroundings, i.e. humans. In this paper we build a predictive model of sensor traces that enables early failure detection by means of a skill memory. Specifically, we propose an architecture based on a biped locomotion solution with improved robustness due to sensory feedback, and extend the concept of Associative Skill Memories (ASM) to periodic movements by introducing several mechanisms into the training workflow, such as linear interpolation and regression into a Dynamical Motion Primitive (DMP) system such that representation becomes time invariant and easily parameterizable. The failure detection mechanism applies statistical tests to determine the optimal operating conditions. Both training and failure testing were conducted on a DARwIn-OP inside a simulation environment to assess and validate the failure detection system proposed. Results show that the system performance in terms of the compromise between sensitivity and specificity is similar with and without the proposed mechanism, while achieving a significant data size reduction due to the periodic approach taken.This work is funded by FEDER Funding supported by the Operational Program Competitive Factors - COMPETE and National Funding supported by the FCT - Portuguese Science Foundation through project PTDC/EEACRO/100655/2008 and Project: FCOMP-01-FEDER-0124-022674.info:eu-repo/semantics/publishedVersio

Perspective historique de robots humanoïdes en Europe

International audienceFrom the very first humanoid automation designed by Leonardo da Vinci in 1495 to Pyrène – a fully force control humanoid robot – designed for research purpose in 2016, this chapter discusses the contributions of Europe in humanoid robot research and development. It is organized around the presentation of the main influential platforms, followed by thematic contributions covering collaborative robots, control, biomechanics, and neurosciences