Adaptive Non-linear Centroidal MPC with Stability Guarantees for Robust Locomotion of Legged Robots

Wedi'i Gadw mewn:

Manylion Llyfryddiaeth
Cyhoeddwyd yn:	arXiv.org (Dec 22, 2024), p. n/a
Prif Awdur:	Elobaid, Mohamed
Awduron Eraill:	Turrisi, Giulio, Rapetti, Lorenzo, Romualdi, Giulio, Dafarra, Stefano, Kawakami, Tomohiro, Chaki, Tomohiro, Yoshiike, Takahide, Semini, Claudio, Pucci, Daniele
Cyhoeddwyd:	Cornell University Library, arXiv.org
Pynciau:	Payloads Robust control Robot dynamics Closed loops Robots Predictive control Adaptive control Control stability Stability Nonlinear control Liapunov functions Parameter uncertainty Nonlinear dynamics Locomotion
Mynediad Ar-lein:	Citation/Abstract Full text outside of ProQuest
Tagiau:	Ychwanegu Tag Dim Tagiau, Byddwch y cyntaf i dagio'r cofnod hwn!

MARC


LEADER	00000nab a2200000uu 4500
001	3148982210
003	UK-CbPIL
022			\|a 2331-8422
035			\|a 3148982210
045	0		\|b d20241222
100	1		\|a Elobaid, Mohamed
245	1		\|a Adaptive Non-linear Centroidal MPC with Stability Guarantees for Robust Locomotion of Legged Robots
260			\|b Cornell University Library, arXiv.org \|c Dec 22, 2024
513			\|a Working Paper
520	3		\|a Nonlinear model predictive locomotion controllers based on the reduced centroidal dynamics are nowadays ubiquitous in legged robots. These schemes, even if they assume an inherent simplification of the robot's dynamics, were shown to endow robots with a step-adjustment capability in reaction to small pushes, and, moreover, in the case of uncertain parameters - as unknown payloads - they were shown to be able to provide some practical, albeit limited, robustness. In this work, we provide rigorous certificates of their closed loop stability via a reformulation of the centroidal MPC controller. This is achieved thanks to a systematic procedure inspired by the machinery of adaptive control, together with ideas coming from Control Lyapunov functions. Our reformulation, in addition, provides robustness for a class of unmeasured constant disturbances. To demonstrate the generality of our approach, we validated our formulation on a new generation of humanoid robots - the 56.7 kg ergoCub, as well as on a commercially available 21 kg quadruped robot, Aliengo.
653			\|a Payloads
653			\|a Robust control
653			\|a Robot dynamics
653			\|a Closed loops
653			\|a Robots
653			\|a Predictive control
653			\|a Adaptive control
653			\|a Control stability
653			\|a Stability
653			\|a Nonlinear control
653			\|a Liapunov functions
653			\|a Parameter uncertainty
653			\|a Nonlinear dynamics
653			\|a Locomotion
700	1		\|a Turrisi, Giulio
700	1		\|a Rapetti, Lorenzo
700	1		\|a Romualdi, Giulio
700	1		\|a Dafarra, Stefano
700	1		\|a Kawakami, Tomohiro
700	1		\|a Chaki, Tomohiro
700	1		\|a Yoshiike, Takahide
700	1		\|a Semini, Claudio
700	1		\|a Pucci, Daniele
773	0		\|t arXiv.org \|g (Dec 22, 2024), p. n/a
786	0		\|d ProQuest \|t Engineering Database
856	4	1	\|3 Citation/Abstract \|u https://www.proquest.com/docview/3148982210/abstract/embedded/ZKJTFFSVAI7CB62C?source=fedsrch
856	4	0	\|3 Full text outside of ProQuest \|u http://arxiv.org/abs/2409.01144