High-resolution Tactile Sensing for Robotic Perception

Abstract:
Why is it so difficult for the present-day robots to act intelligently in the real-world environment? A major challenge lies in the lack of adequate tactile sensing technologies. Robots need tactile sensing to understand the physical environment, and detect the contact states during manipulation. A recently developed high-resolution tactile sensor, GelSight, which measures detailed information about the geometry and traction field on the contact surface, shows substantial potential for extending the application of robot tactile sensing. The major questions are: (1) What physical information is available from the high-resolution sensor? (2) How can the robot interpret and use this information?

This thesis aims at addressing the two questions above. On the one hand, the tactile feedback helps robots on manipulation tasks. I investigate various techniques for detecting incipient slip and full slip during contact with objects. On the other hand, tactile sensing also helps a robot to better understand the physical environment, i.e. exploration tasks. I will present my work on using tactile sensing to estimate the hardness of arbitrary objects, and making a robot autonomously explore the comprehensive properties of common clothing. I also show our work on unsupervised exploration of latent properties of fabrics through cross-modal learning with vision and touch.