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Main Authors: Lee, Haegu, Kim, Yitaek, Staven, Victor Melbye, Sloth, Christoffer
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2503.08222
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author Lee, Haegu
Kim, Yitaek
Staven, Victor Melbye
Sloth, Christoffer
author_facet Lee, Haegu
Kim, Yitaek
Staven, Victor Melbye
Sloth, Christoffer
contents The strength of the human hand lies in its ability to manipulate small objects precisely and robustly. In contrast, simple robotic grippers have low dexterity and fail to handle small objects effectively. This is why many automation tasks remain unsolved by robots. This paper presents an optimization-based framework for in-hand manipulation with a robotic hand equipped with compact Magnetic Tactile Sensors (MTSs). The small form factor of the robotic hand from Shadow Robot introduces challenges in estimating the state of the object while satisfying contact constraints. To address this, we formulate a trajectory optimization problem using Nonlinear Programming (NLP) for finger movements while ensuring contact points to change along the geometry of the fingers. Using the optimized trajectory from the solver, we implement and test an open-loop controller for rolling motion. To further enhance robustness and accuracy, we introduce a force controller for the fingers and a state estimator for the object utilizing MTSs. The proposed framework is validated through comparative experiments, showing that incorporating the force control with compliance consideration improves the accuracy and robustness of the rolling motion. Rolling an object with the force controller is 30\% more likely to succeed than running an open-loop controller. The demonstration video is available at https://youtu.be/6J_muL_AyE8.
format Preprint
id arxiv_https___arxiv_org_abs_2503_08222
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Trajectory Optimization for In-Hand Manipulation with Tactile Force Control
Lee, Haegu
Kim, Yitaek
Staven, Victor Melbye
Sloth, Christoffer
Robotics
The strength of the human hand lies in its ability to manipulate small objects precisely and robustly. In contrast, simple robotic grippers have low dexterity and fail to handle small objects effectively. This is why many automation tasks remain unsolved by robots. This paper presents an optimization-based framework for in-hand manipulation with a robotic hand equipped with compact Magnetic Tactile Sensors (MTSs). The small form factor of the robotic hand from Shadow Robot introduces challenges in estimating the state of the object while satisfying contact constraints. To address this, we formulate a trajectory optimization problem using Nonlinear Programming (NLP) for finger movements while ensuring contact points to change along the geometry of the fingers. Using the optimized trajectory from the solver, we implement and test an open-loop controller for rolling motion. To further enhance robustness and accuracy, we introduce a force controller for the fingers and a state estimator for the object utilizing MTSs. The proposed framework is validated through comparative experiments, showing that incorporating the force control with compliance consideration improves the accuracy and robustness of the rolling motion. Rolling an object with the force controller is 30\% more likely to succeed than running an open-loop controller. The demonstration video is available at https://youtu.be/6J_muL_AyE8.
title Trajectory Optimization for In-Hand Manipulation with Tactile Force Control
topic Robotics
url https://arxiv.org/abs/2503.08222