Safe and Autonomous Physical Human-Aware Robot Interaction

SAPHARI

SAPHARI Logo
SAPHARI Logo
Credit:
PR

SAPHARI (Safe and Autonomous Physical Human-Aware Robot Interaction) will perform a fundamental paradigm shift in robot development in the sense that we place the human at the centre of the entire design. The project will take a big step further along the human-centered roadmap by addressing all essential aspects of safe, intuitive physical interaction between humans and complex, human-like robotic systems in a strongly interconnected manner.

  
Runtime
2011-11-01 until 2015-10-31
Project Partner
• Università degli Studi di Roma "La Sapienza" (UNIROMA1)
• Fondazione Istituto Italiano di Tecnologia (IIT)
• AIRBUS Group
• Deutsches Zentrum für Luft- und Raumfahrt (DLR)
• Fraunhofer-Institut für Optronik, Systemtechnik und Bildauswertung (IOSB)
• KUKA
• Centre national de la recherche scientifique (CRNS-LAAS)
• Technische Universität München (TUM)
• Università degli Studi di Napoli Federico II (UNINA)
• Università di Pisa (UNIPI)
• Universität Bremen
Website
Application Fields
Applications with human-robot interaction in industrial or domestic environments
Funding
FP7-ICT-2011-7, Grant no: 287513

Project details  

Recent progress in physical Human-Robot Interaction (pHRI) showed that active and safe workspace sharing becomes possible in principle. Inspired by these results, SAPHARI will perform a fundamental paradigm shift in robot development in the sense that we place the human as the centre of the entire design. We address all essential aspects of safe, intuitive physical interaction between humans and complex, human-like robotic systems in a strongly interconnected manner. While encompassing safety issues based on biomechanical analysis, human-friendly hardware design, and interaction control strategies, the project will develop and validate perceptive and cognitive key components that enable robots to track, understand and predict human motions in a weakly structured dynamic environment in real-time. Apart from developing the necessary capabilities for interactive autonomy, we will tightly incorporate the human safety also at the cognitive level. This will enable the robots to react or physically interact with humans in a safe and autonomous way. Biomechanical knowledge and biologically motivated variable compliance actuators will be used to design bimanual manipulation systems close to human properties and performance. Planning motions and tasks of such complex systems in real-time require new concepts, including tight coupling of control and planning, that lead to new reactive action generation behaviours. Moreover, self-explaining interaction and communication frameworks will be developed to enhance the system usability. The project focuses on two industrial use cases that explicitly require contacts and force exchange in human-robot co-work, as well as on professional service scenarios in hospitals, in which a medical staff and an assisting robot interact closely during daily work. Results of this project are expected to strongly impact all applications where interactive robots can assist humans and release them from dangerous or routine tasks.