This paper presents experimentally realized bipedal robotic walking using ideal torque controllers via a novel approach termed the ideal model resolved motion method (IM-RMM), where a system's ideal closed-loop dynamics are integrated forward from the actual state of the hardware to provide desired positions and velocity commands to a PD controller. By combining this method with gaits generated using the Human-Inspired Control framework, walking was realized experimentally on the DURUS platform, designed and built by SRI, and achieved with minimal system identification. For comparison, two controllers, one using feedback linearization and one using Control Lyapunov Function based Quadratic Programs (CLF-QP), both realized through IM-RMM, ar...
Design and control of the bipedal humanoid robot locomotion are challenging areas of research. Accur...
International audienceIn this paper we present the experimental validation of a framework for the sy...
Abstract—This paper presents a human-inspired control approach to bipedal robotic walking: utilizing...
This paper presents experimentally realized bipedal robotic walking using ideal torque controllers v...
This thesis presents an application of hybrid zero dynamics to realize underactuated bipedal walking...
This paper addresses the problem of controlling underactuated bipedal walking robots in the presence...
Abstract — This paper presents the first steps toward going from human data to formal controller des...
This paper presents a novel method of stabilizing hybrid models of torque-constrained, underactuated...
This paper presents two strategies for designing underactuated, planar robotic walking gaits and for...
Abstract — This paper describes a torque control scheme unifying feedback PD control and feed-forwar...
This paper describes a torque control scheme unifying feedback PD control and feed-forward impedance...
This dissertation proposes advanced feedback controllers that allow bipedal robots to perform anthro...
This paper presents a methodology for achieving efficient multi-domain underactuated bipedal walking...
This thesis presents a model-based controller design framework for bipedal robots that combines ener...
Abstract — This paper presents a method for achieving stable periodic walking, consisting of phases ...
Design and control of the bipedal humanoid robot locomotion are challenging areas of research. Accur...
International audienceIn this paper we present the experimental validation of a framework for the sy...
Abstract—This paper presents a human-inspired control approach to bipedal robotic walking: utilizing...
This paper presents experimentally realized bipedal robotic walking using ideal torque controllers v...
This thesis presents an application of hybrid zero dynamics to realize underactuated bipedal walking...
This paper addresses the problem of controlling underactuated bipedal walking robots in the presence...
Abstract — This paper presents the first steps toward going from human data to formal controller des...
This paper presents a novel method of stabilizing hybrid models of torque-constrained, underactuated...
This paper presents two strategies for designing underactuated, planar robotic walking gaits and for...
Abstract — This paper describes a torque control scheme unifying feedback PD control and feed-forwar...
This paper describes a torque control scheme unifying feedback PD control and feed-forward impedance...
This dissertation proposes advanced feedback controllers that allow bipedal robots to perform anthro...
This paper presents a methodology for achieving efficient multi-domain underactuated bipedal walking...
This thesis presents a model-based controller design framework for bipedal robots that combines ener...
Abstract — This paper presents a method for achieving stable periodic walking, consisting of phases ...
Design and control of the bipedal humanoid robot locomotion are challenging areas of research. Accur...
International audienceIn this paper we present the experimental validation of a framework for the sy...
Abstract—This paper presents a human-inspired control approach to bipedal robotic walking: utilizing...