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arxiv: 2504.06662 · v4 · pith:R4L5GUCA · submitted 2025-04-09 · cs.RO

RAMBO: RL-Augmented Model-Based Whole-Body Control for Loco-Manipulation

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classification cs.RO
keywords model-basedprecisecontrolloco-manipulationramborobustnesswhilefeedback
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Loco-manipulation, physical interaction of various objects that is concurrently coordinated with locomotion, remains a major challenge for legged robots due to the need for both precise end-effector control and robustness to unmodeled dynamics. While model-based controllers provide precise planning via online optimization, they are limited by model inaccuracies. In contrast, learning-based methods offer robustness, but they struggle with precise modulation of interaction forces. We introduce RAMBO, a hybrid framework that integrates model-based whole-body control within a feedback policy trained with reinforcement learning. The model-based module generates feedforward torques by solving a quadratic program, while the policy provides feedback corrective terms to enhance robustness. We validate our framework on a quadruped robot across a diverse set of real-world loco-manipulation tasks, such as pushing a shopping cart, balancing a plate, and holding soft objects, in both quadrupedal and bipedal walking. Our experiments demonstrate that RAMBO enables precise manipulation capabilities while achieving robust and dynamic locomotion.

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Cited by 2 Pith papers

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  2. FLARE: Robot Learning with Implicit World Modeling

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