Home /Research /GraspGraphNet: Graph-Structured Multi-Embodiment Dexterous Grasp Generation
MANIPULATION

GraspGraphNet: Graph-Structured Multi-Embodiment Dexterous Grasp Generation

Yeonseo Lee, Taeyeop Lee, Hyosup Shin, Guebin Hwang, Sungho Jo

Year
2026
Access
Open access

Abstract

Dexterous grasp generation across robot hands is challenging because hands differ in kinematic topology, actuation dimensions, and native command spaces. We introduce GraspGraphNet, a topology-aware grasp generation framework that represents each hand as a URDF-derived kinematic graph and directly generates executable palm poses and joint configurations. GraspGraphNet combines hierarchical object surface encoding, differentiable forward kinematics, and dynamic world-edge message passing to model evolving robot-object interactions. It applies conditional flow matching directly in executable palm-pose and joint-state space, avoiding post-processing optimization, inverse kinematics, and retargeting. Using a shared model trained on Barrett Hand, Allegro Hand, and Shadow Hand, GraspGraphNet achieves an average success rate of 83.48% with 40ms inference time per grasp on a 40-object benchmark. Without retraining, the same model achieves 72.70% success on controlled finger-removal variants, demonstrating robustness to hand-topology variations. These results suggest that graph-structured hand representations can effectively support dexterous grasp generation across robot hands with different kinematic structures. Project: https://lysees.github.io/graspgraphnet-page

Keywords

dexterous graspgraph neural networkmulti-embodimenttopology-awaregenerative model

Related papers

Browse all MANIPULATION papers