Enhancing Tactile-based Reinforcement Learning for Robotic Control

Agentic AI

Published: arXiv: 2510.21609v1

Authors

Elle Miller Trevor McInroe David Abel Oisin Mac Aodha Sethu Vijayakumar

Abstract

Achieving safe, reliable real-world robotic manipulation requires agents to evolve beyond vision and incorporate tactile sensing to overcome sensory deficits and reliance on idealised state information. Despite its potential, the efficacy of tactile sensing in reinforcement learning (RL) remains inconsistent. We address this by developing self-supervised learning (SSL) methodologies to more effectively harness tactile observations, focusing on a scalable setup of proprioception and sparse binary contacts. We empirically demonstrate that sparse binary tactile signals are critical for dexterity, particularly for interactions that proprioceptive control errors do not register, such as decoupled robot-object motions. Our agents achieve superhuman dexterity in complex contact tasks (ball bouncing and Baoding ball rotation). Furthermore, we find that decoupling the SSL memory from the on-policy memory can improve performance. We release the Robot Tactile Olympiad (RoTO) benchmark to standardise and promote future research in tactile-based manipulation. Project page: https://elle-miller.github.io/tactile_rl

Paper Summary

Problem

The main problem addressed in this research paper is the limitation of current robotic manipulation systems, which rely heavily on visual information and are not able to safely and reliably interact with their environment. The authors aim to address this by incorporating tactile sensing into reinforcement learning (RL) to enable robots to feel and manipulate objects.

Key Innovation

The key innovation of this work is the development of self-supervised learning (SSL) methodologies to effectively harness tactile observations and improve robotic dexterity. The authors propose four new SSL objectives for tactile agents, including tactile reconstruction, full reconstruction, forward dynamics, and tactile forward dynamics, which demonstrate superior performance to RL-only approaches. They also show that decoupling the SSL training data from the on-policy memory can improve performance.

Practical Impact

This research has significant practical implications for the development of safe and reliable robotic manipulation systems. By enabling robots to feel and manipulate objects, this work can lead to breakthroughs in areas such as: * Assisted living: robots that can safely lift and move elderly people or people with disabilities * Healthcare: robots that can assist with medical procedures or provide therapy * Manufacturing: robots that can assemble and manipulate objects with precision and dexterity The authors also release the Robot Tactile Olympiad (RoTO) benchmark to standardize and promote future research in tactile-based manipulation.

Analogy / Intuitive Explanation

Imagine trying to play a piano without being able to see the keys. You would need to rely on touch and feel to navigate the keys and produce music. Similarly, robots need to be able to feel and manipulate objects in order to perform tasks safely and reliably. The authors' work is like developing a way for robots to "feel" their environment, allowing them to interact with objects in a more intuitive and human-like way.

Paper Information

Categories:

cs.RO cs.LG

Published Date:

arXiv ID:

2510.21609v1

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