Katayon Radkhah scite author profile

Bioinspired legged locomotion comprises different aspects, such as (i) benefiting from reduced complexity control approaches as observed in humans/animals, (ii) combining embodiment with the controllers and (iii) reflecting neural control mechanisms. One of the most important lessons learned from nature is the significant role of compliance in simplifying control, enhancing energy efficiency and robustness against perturbations for legged locomotion. In this research, we investigate how body morphology in combination with actuator design may facilitate motor control of leg function. Inspired by the human leg muscular system, we show that biarticular muscles have a key role in balancing the upper body, joint coordination and swing leg control. Appropriate adjustment of biarticular spring rest length and stiffness can simplify the control and also reduce energy consumption. In order to test these findings, the BioBiped3 robot was developed as a new version of BioBiped series of biologically inspired, compliant musculoskeletal robots. In this robot, three-segmented legs actuated by mono- and biarticular series elastic actuators mimic the nine major human leg muscle groups. With the new biarticular actuators in BioBiped3, novel simplified control concepts for postural balance and for joint coordination in rebounding movements (drop jumps) were demonstrated and approved.

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Concept and Design of the Biobiped1 Robot for Human-Like Walking and Running

Radkhah

Maufroy

Maus

et al. 2011

Int. J. Human. Robot.

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Biomechanics research shows that the ability of the human locomotor system depends on the functionality of a highly compliant motor system that enables a variety of different motions (such as walking and running) and control paradigms (such as flexible combination of feedforward and feedback controls strategies) and reliance on stabilizing properties of compliant gaits. As a new approach of transferring this knowledge into a humanoid robot, the design and implementation of the first of a planned series of biologically inspired, compliant, and musculoskeletal robots is presented in this paper. Its three-segmented legs are actuated by compliant mono- and biarticular structures, which mimic the main nine human leg muscle groups, by applying series elastic actuation consisting of cables and springs in combination with electrical actuators. By means of this platform, we aim to transfer versatile human locomotion abilities, namely running and later on walking, into one humanoid robot design. First experimental results for passive rebound, as well as push-off with active knee and ankle joints, and synchronous and alternate hopping are described and discussed. BioBiped1 will serve for further evaluation of the validity of biomechanical concepts for humanoid locomotion.

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Detailed dynamics modeling of BioBiped's monoarticular and biarticular tendon-driven actuation system

Radkhah

Lens

Stryk

2012

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Dynamic parameter identification for the CRS A460 robot

Radkhah

Kulić

Croft

2007

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Hopping control for the musculoskeletal bipedal robot: BioBiped

Sharbafi

Radkhah

Stryk

et al. 2014

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Katayon Radkhah

A new biarticular actuator design facilitates control of leg function in BioBiped3

Concept and Design of the Biobiped1 Robot for Human-Like Walking and Running

Detailed dynamics modeling of BioBiped's monoarticular and biarticular tendon-driven actuation system

Dynamic parameter identification for the CRS A460 robot

Hopping control for the musculoskeletal bipedal robot: BioBiped

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