CoorGrasp: Coordinated Contact Control for Adaptive Dexterous Grasping Under Uncertainty

📅 2026-07-03
📈 Citations: 0
Influential: 0
📄 PDF
🤖 AI Summary
This work addresses the challenge of open-loop grasping under uncertainty in object shape and pose, where poor contact coordination often leads to slippage or failure. The authors propose a tactile feedback–based model predictive controller that enables coordinated multi-contact interaction and adaptive force modulation during both approach and grasp phases. Key innovations include perception-driven phase segmentation, arm–hand协同 compensation for pose errors, and a balanced adaptive force coordination mechanism. By analytically linking contact forces to joint motions, the method remains compatible with diverse grasp pose generation strategies. Evaluated across 15,000 simulations involving 478 objects and eight physical experiments, the approach significantly improves grasp success rates while effectively suppressing unintended object motion.
📝 Abstract
While recent research has focused heavily on dexterous grasp pose generation, less attention has been devoted to the execution of planned grasps. Under shape and position uncertainty, open-loop execution often yields uncoordinated contacts, causing undesired in-hand object motion and even grasp failures. To address this, this paper proposes a tactile-driven model predictive controller for adaptive and delicate execution of diverse dexterous grasps. Our approach emphasizes multi-contact coordination across both approaching and grasping phases, with three key novelties: (i) coordination-aware phase separation, (ii) arm-hand coordination to compensate for position errors, and (iii) adaptive force coordination to increase contact forces in a balanced manner. An analytical model is employed to relate contact forces to robot joint motions for predictive control. Our formulation imposes no restrictions on grasp types or contact configurations and integrates seamlessly with state-of-the-art grasp pose generation methods. We validate the approach through large-scale simulations involving 15k grasps across 478 objects on three robotic hands, and real-world experiments on 8 objects. Results demonstrate that our method achieves higher grasp success rates and reduced undesired object movements.
Problem

Research questions and friction points this paper is trying to address.

dexterous grasping
contact coordination
uncertainty
grasp execution
in-hand object motion
Innovation

Methods, ideas, or system contributions that make the work stand out.

tactile-driven control
model predictive control
multi-contact coordination
adaptive grasping
arm-hand coordination