Tactile Sensor
Tactile sensors aim to replicate the human sense of touch in robotic systems, enabling robots to perceive contact forces, shapes, textures, and temperatures. Current research emphasizes developing more versatile, affordable, and easily integrable sensors, often employing vision-based systems, soft materials, and magnetic or capacitive sensing principles. Machine learning, particularly neural networks (including transformers and recurrent graph neural networks), and physics-based modeling (like finite element methods) are crucial for processing sensor data and reconstructing complex tactile information. These advancements are significantly impacting robotics, enabling more dexterous manipulation, improved object recognition, and safer human-robot interaction in diverse applications.
Papers
Design of a Five-Fingered Hand with Full-Fingered Tactile Sensors Using Conductive Filaments and Its Application to Bending after Insertion Motion
Kazuhiro Miyama, Shun Hasegawa, Kento Kawaharazuka, Naoya Yamaguchi, Kei Okada, Masayuki Inaba
A Machine Learning Approach to Contact Localization in Variable Density Three-Dimensional Tactile Artificial Skin
Carson Kohlbrenner, Mitchell Murray, Yutong Zhang, Caleb Escobedo, Thomas Dunnington, Nolan Stevenson, Nikolaus Correll, Alessandro Roncone
A Sensor Position Localization Method for Flexible, Non-Uniform Capacitive Tactile Sensor Arrays
Carson Kohlbrenner, Caleb Escobedo, Nataliya Nechyporenko, Alessandro Roncone
Interaction force estimation for tactile sensor arrays: Toward tactile-based interaction control for robotic fingers
Elie Chelly, Andrea Cherubini, Philippe Fraisse, Faiz Ben Amar, Mahdi Khoramshahi
Flexible electrical impedance tomography for tactile interfaces
Huazhi Dong, Sihao Teng, Xiaopeng Wu, Xu Han, Francesco Giorgio-Serchi, Yunjie Yang