The paper introduces an optimization-based approach for loco-manipulation (locomotion and manipulation) using the COBRA snake robot platform. COBRA is a morpho-functional robot with 11 actuated joints that enables high-fidelity modeling for manipulating objects on flat surfaces.
The key highlights are:
The paper presents a mathematical framework for incorporating non-impulsive unilateral contact forces into the motion optimization problem for COBRA. This allows the robot to manipulate objects through continuous body-object interactions.
The optimization approach is formulated to find optimal joint trajectories that respect complementarity conditions between the contact forces and relative constraint velocities. This enables effective guidance of the robot's joints for desired object movements.
High-fidelity simulation results demonstrate COBRA's ability to lift a box from the ground, place it on a raised platform, and translate the box to a new location using lateral rolling gaits.
Experimental results on the physical COBRA robot validate the effectiveness of the proposed optimization-based approach in manipulating objects on flat surfaces and ascending ramps.
The paper discusses future work to enhance COBRA's capabilities by integrating tactile sensors for online and real-time path planning/re-planning based on feedback from the environment.
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by Adarsh Salag... alle arxiv.org 04-15-2024
https://arxiv.org/pdf/2404.08174.pdfDomande più approfondite