TY - JOUR
T1 - On making robots understand safety
T2 - Embedding injury knowledge into control
AU - Haddadin, Sami
AU - Haddadin, Simon
AU - Khoury, Augusto
AU - Rokahr, Tim
AU - Parusel, Sven
AU - Burgkart, Rainer
AU - Bicchi, Antonio
AU - Albu-Schäffer, Alin
PY - 2012/11
Y1 - 2012/11
N2 - Enabling robots to safely interact with humans is an essential goal of robotics research. The developments achieved over recent years in mechanical design and control made it possible to have active cooperation between humans and robots in rather complex situations. For this, safe robot behavior even under worst-case situations is crucial and forms also a basis for higher-level decisional aspects. For quantifying what safe behavior really means, the definition of injury, as well as understanding its general dynamics, are essential. This insight can then be applied to design and control robots such that injury due to robot-human impacts is explicitly taken into account. In this paper we approach the problem from a medical injury analysis point of view in order to formulate the relation between robot mass, velocity, impact geometry and resulting injury qualified in medical terms. We transform these insights into processable representations and propose a motion supervisor that utilizes injury knowledge for generating safe robot motions. The algorithm takes into account the reflected inertia, velocity, and geometry at possible impact locations. The proposed framework forms a basis for generating truly safe velocity bounds that explicitly consider the dynamic properties of the manipulator and human injury.
AB - Enabling robots to safely interact with humans is an essential goal of robotics research. The developments achieved over recent years in mechanical design and control made it possible to have active cooperation between humans and robots in rather complex situations. For this, safe robot behavior even under worst-case situations is crucial and forms also a basis for higher-level decisional aspects. For quantifying what safe behavior really means, the definition of injury, as well as understanding its general dynamics, are essential. This insight can then be applied to design and control robots such that injury due to robot-human impacts is explicitly taken into account. In this paper we approach the problem from a medical injury analysis point of view in order to formulate the relation between robot mass, velocity, impact geometry and resulting injury qualified in medical terms. We transform these insights into processable representations and propose a motion supervisor that utilizes injury knowledge for generating safe robot motions. The algorithm takes into account the reflected inertia, velocity, and geometry at possible impact locations. The proposed framework forms a basis for generating truly safe velocity bounds that explicitly consider the dynamic properties of the manipulator and human injury.
KW - Physical human-robot interaction
KW - biomechanics
KW - human injury
KW - impact dynamics
KW - nonlinear control
KW - robot standardization
KW - safety
KW - soft-tissue
UR - http://www.scopus.com/inward/record.url?scp=84870516408&partnerID=8YFLogxK
U2 - 10.1177/0278364912462256
DO - 10.1177/0278364912462256
M3 - Article
AN - SCOPUS:84870516408
SN - 0278-3649
VL - 31
SP - 1578
EP - 1602
JO - International Journal of Robotics Research
JF - International Journal of Robotics Research
IS - 13
ER -