Functional Grasping
Functional grasping research aims to enable robots to grasp and manipulate objects effectively, mirroring human dexterity and adaptability. Current efforts concentrate on developing robust and generalizable grasping policies using reinforcement learning, novel geometric representations (e.g., point clouds, graph neural networks), and large language models to incorporate semantic understanding of tasks and objects. This field is crucial for advancing robotics in diverse applications, from assistive devices and surgery to warehouse automation and household robotics, by improving the reliability and efficiency of robotic manipulation.
Papers
ShapeGrasp: Zero-Shot Task-Oriented Grasping with Large Language Models through Geometric Decomposition
Samuel Li, Sarthak Bhagat, Joseph Campbell, Yaqi Xie, Woojun Kim, Katia Sycara, Simon Stepputtis
Five-fingered Hand with Wide Range of Thumb Using Combination of Machined Springs and Variable Stiffness Joints
Shogo Makino, Kento Kawaharazuka, Ayaka Fujii, Masaya Kawamura, Tasuku Makabe, Moritaka Onitsuka, Yuki Asano, Kei Okada, Koji Kawasaki, Masayuki Inaba