Skin-Inspired Triple Tactile Sensors Integrated on Robotic Fingers for Bimanual Manipulation in Human-Cyber-Physical Systems

Collaborative robots are predicted to interact physically with humans in human-cyber-physical systems (HCPSs). Robotic hands are able to record force and temperature simultaneously through soft and conformable sensors applied over finger surfaces and conforming to the complex curved geometries of automatic machines with tactile perception. Here, skin-inspired triple tactile (SITT) sensors are integrated into robotic fingers to enable precise bimanual grasping. The SITT sensor has skin-inspired multilayer microstructures, which integrate three sensors, namely, an interdigital electrode sensor, a flexible force sensor, and a temperature sensor. The SITT sensor can simultaneously or independently measure a material's dielectric property, tactile force and temperature. An HCPS based on SITT sensors, a data acquisition board, bimanual robotic hands, and human-robot interaction software is developed for efficient bimanual manipulation. Through 3C assembly experiments, the designed HCPS is demonstrated to execute complex tasks. This research presents a novel methodology for constructing robust tactile sensors for robotic fingers in a bimanual manipulation system, and it presents significant potential across various aspects of intelligent production, including sensitive object handling, adaptive manipulation, and interactive robotics applications. Note to Practitioners -This work aims to overcome the challenge of skin-inspired triple tactile (SITT) sensors developed for robotic fingers in a human-robot collaborative assembly scenario, which can also be used in many other similar human-robot/machine collaborations (e.g., wearable prosthetics with tactile feedback) with practical value. Its capability to accurately measure the touched objects' information (e.g., material dielectric property, force, temperature) is crucial for the bimanual robot to successfully interact with human operators. HCPS is valuable for its potential to achieve complicated interactions among humans, cyber systems, and physical resources. Collaborative robots with tactile sensors are expected to interact physically with humans in the HCPS. In this paper, we report SITT sensors integrated on robotic fingers to enable precise bimanual grasping. They can simultaneously or independently measure material dielectric properties and tactile forces and record temperature. By combining tactile perception information and a related control method, our smart bimanual robotic hands with the developed HCPS