From Power to Precision: Learning Fine-grained Dexterity for Multi-fingered Robotic Hands
Marc Steiner
Human grasps can be roughly categorized into two types: power grasps and precision grasps. Precision grasping enables tool use and is believed to have influence...
Reporting by Jianglong Ye, SwissFinanceAI Redaktion
Abstract
Human grasps can be roughly categorized into two types: power grasps and precision grasps. Precision grasping enables tool use and is believed to have influenced human evolution. Today's multi-fingered robotic hands are effective in power grasps, but for tasks requiring precision, parallel grippers are still more widely adopted. This contrast highlights a key limitation in current robotic hand design: the difficulty of achieving both stable power grasps and precise, fine-grained manipulation within a single, versatile system. In this work, we bridge this gap by jointly optimizing the control and hardware design of a multi-fingered dexterous hand, enabling both power and precision manipulation. Rather than redesigning the entire hand, we introduce a lightweight fingertip geometry modification, represent it as a contact plane, and jointly optimize its parameters along with the corresponding control. Our control strategy dynamically switches between power and precision manipulation and simplifies precision control into parallel thumb-index motions, which proves robust for sim-to-real transfer. On the design side, we leverage large-scale simulation to optimize the fingertip geometry using a differentiable neural-physics surrogate model. We validate our approach through extensive experiments in both sim-to-real and real-to-real settings. Our method achieves an 82.5% zero-shot success rate on unseen objects in sim-to-real precision grasping, and a 93.3% success rate in challenging real-world tasks involving bread pinching. These results demonstrate that our co-design framework can significantly enhance the fine-grained manipulation ability of multi-fingered hands without reducing their ability for power grasps. Our project page is at https://jianglongye.com/power-to-precision
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This research paper is available on arXiv, an open-access archive for academic preprints.
Citation
Jianglong Ye. "From Power to Precision: Learning Fine-grained Dexterity for Multi-fingered Robotic Hands." arXiv preprint. 2025-11-17. http://arxiv.org/abs/2511.13710v1
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Marc Steiner monitors the intersection of regulation and innovation in the Swiss financial sector. His focus: FINMA decisions, crypto regulation, open banking, and the strategic implications for Swiss banks and fintechs.
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References
- [1]ResearchCredibility: 9/10Jianglong Ye. "From Power to Precision: Learning Fine-grained Dexterity for Multi-fingered Robotic Hands." arXiv.org. November 17, 2025. Accessed November 18, 2025.
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Original Source
This article is based on From Power to Precision: Learning Fine-grained Dexterity for Multi-fingered Robotic Hands (arXiv.org)
