Open AccessNew Joint Design to Create a More Natural and Efficient Biped
Author(s) -
Giuseppina Gini,
Umberto Scarfogliero,
Michele Folgheraiter
Publication year - 2009
Publication title -
applied bionics and biomechanics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.397
H-Index - 23
eISSN - 1754-2103
pISSN - 1176-2322
DOI - 10.1155/2009/606309
Subject(s) - actuator , humanoid robot , controller (irrigation) , robot , computer science , joint stiffness , joint (building) , focus (optics) , adaptability , simulation , biped robot , control engineering , muscle architecture , stiffness , engineering , artificial intelligence , control theory (sociology) , control (management) , structural engineering , medicine , ecology , physics , optics , anatomy , agronomy , biology
This paper presents a human-oriented approach to design the mechanical architecture and the joint controller for a biped robot. Starting from the analysis of the human lower limbs, we figured out which features of the human legs are fundamental for a correct walking motion, and can be adopted in the mechanical design of a humanoid robot. We focus here on the knee, designed as a compliant human-like knee instead of a classical pin-joint, and on the foot, characterised by the mobility and lightness of the human foot. We implemented an elastic actuator, with a simple position control paradigm that sets the joint stiffness in real time, and developed the basic controller. Results in simulation are discussed. In our approach the robot gains in adaptability and energetic efficiency, which are the most challenging issues for a biped robot.
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