SENSE-STEP: Learning Sim-to-Real Locomotion for a Sensory-Enabled Soft Quadruped Robot

Agentic AI

Published: arXiv: 2602.13078v1

Authors

Storm de Kam Ebrahim Shahabi Cosimo Della Santina

Abstract

Robust closed-loop locomotion remains challenging for soft quadruped robots due to high-dimensional dynamics, actuator hysteresis, and difficult-to-model contact interactions, while conventional proprioception provides limited information about ground contact. In this paper, we present a learning-based control framework for a pneumatically actuated soft quadruped equipped with tactile suction-cup feet, and we validate the approach experimentally on physical hardware. The control policy is trained in simulation through a staged learning process that starts from a reference gait and is progressively refined under randomized environmental conditions. The resulting controller maps proprioceptive and tactile feedback to coordinated pneumatic actuation and suction-cup commands, enabling closed-loop locomotion on flat and inclined surfaces. When deployed on the real robot, the closed-loop policy outperforms an open-loop baseline, increasing forward speed by 41% on a flat surface and by 91% on a 5-degree incline. Ablation studies further demonstrate the role of tactile force estimates and inertial feedback in stabilizing locomotion, with performance improvements of up to 56% compared to configurations without sensory feedback.

Paper Summary

Problem

Robust closed-loop locomotion remains a significant challenge for soft quadruped robots. These robots are designed to navigate complex environments safely and efficiently, but their soft structures deform in complex ways, making it difficult to model and control their dynamics. Conventional proprioceptive sensors, such as joint encoders, are insufficient for soft robots, and rigid kinematic models cannot accurately represent their deformations.

Key Innovation

The research paper presents a learning-based control framework for a tactile soft quadruped robot. The framework combines behavior cloning from a reference gait with domain-randomized reinforcement learning, enabling safe exploration and effective policy refinement in simulation. The approach uses novel suction-cup sensors to provide tactile force estimates, which are integrated with proprioceptive and exteroceptive signals to inform the robot's locomotion.

Practical Impact

This research has significant practical implications for soft quadruped robots. The learning-based control framework enables these robots to navigate complex environments more efficiently and safely. The results show that closed-loop policies outperform open-loop control, increasing flat-terrain speed by 41% and incline speed by 91%. The framework also stabilizes body posture, maintaining near-horizontal orientation during locomotion. This research offers a foundation for future work on more complex terrains and enhanced closed-loop behaviors.

Analogy / Intuitive Explanation

Imagine trying to walk on a tightrope. The tightrope represents the complex terrain that soft quadruped robots need to navigate. The robot's soft structures are like its balance, which needs to be carefully controlled to stay upright and move forward. The learning-based control framework is like a personal trainer that helps the robot learn to balance and move more efficiently, using feedback from its sensors to adjust its movements.

Paper Information

Categories:

cs.RO

Published Date:

arXiv ID:

2602.13078v1

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