Walking with perturbations: a guide for biped humans and robots

Duysens, Jaak; Forner-Cordero, Arturo

doi:10.1088/1748-3190/aada54

Cited by 30 publications

(26 citation statements)

References 377 publications

(714 reference statements)

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“…There was clear evidence that young healthy subjects adapt to the auditory metronome beat during gait. This underscores the influence of supraspinal inputs on the purported Central Pattern Generators (CPG) of gait [33] supporting the role of a cortical loop in a hypothetical gait CPG as has been proposed by others [34][35][36][37].…”

Section: Discussionsupporting

confidence: 80%

Effects of supraspinal feedback on human gait: rhythmic auditory distortion

Forner-Cordero

Pinho

Umemura

et al. 2019

J NeuroEngineering Rehabil

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BackgroundDifferent types of sound cues have been used to adapt the human gait rhythm. We investigated whether young healthy volunteers followed subliminal metronome rhythm changes during gait.MethodsTwenty-two healthy adults walked at constant speed on a treadmill following a metronome sound cue (period 566 msec). The metronome rhythm was then either increased or decreased, without informing the subjects, at 1 msec increments or decrements to reach, respectively, a low (596 msec) or a high frequency (536 msec) plateaus. After 30 steps at one of these isochronous conditions, the rhythm returned to the original period with decrements or increments of 1 msec. Motion data were recorded with an optical measurement system to determine footfall. The relative phase between sound cue (stimulus) and foot contact (response) were compared.ResultsGait was entrained to the rhythmic auditory stimulus and subjects subconsciously adapted the step time and length to maintain treadmill speed, while following the rhythm changes. In most cases there was a lead error: the foot contact occurred before the sound cue. The mean error or the absolute mean relative phase increased during the isochronous high (536 msec) or low frequencies (596 msec).ConclusionThese results showed that the gait period is strongly “entrained” with the first metronome rhythm while subjects still followed metronome changes with larger error. This suggests two processes: one slow-adapting, supraspinal oscillator with persistence that predicts the foot contact to occur ahead of the stimulus, and a second fast process linked to sensory inputs that adapts to the mismatch between peripheral sensory input (foot contact) and supraspinal sensory input (auditory rhythm).

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Section: Discussionsupporting

confidence: 80%

Effects of supraspinal feedback on human gait: rhythmic auditory distortion

Forner-Cordero

Pinho

Umemura

et al. 2019

J NeuroEngineering Rehabil

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“…The computation time reached in this work is around 0.0014 ms. Other works take further the idea of comparing with human locomotion by restricting certain joints and observing the effects and torque changes in the robot [27]. Symmetricity of gait cycle patterns is analyzed in detail in Reference [28]. A thorough survey on stability criteria in biped robots is presented in Reference [28] as well.…”

Section: Zero Moment Point Approachesmentioning

confidence: 99%

“…Symmetricity of gait cycle patterns is analyzed in detail in Reference [28]. A thorough survey on stability criteria in biped robots is presented in Reference [28] as well.…”

Section: Zero Moment Point Approachesmentioning

confidence: 99%

Learning an Efficient Gait Cycle of a Biped Robot Based on Reinforcement Learning and Artificial Neural Networks

Morales¹,

Rufino²

2019

Applied Sciences

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Programming robots for performing different activities requires calculating sequences of values of their joints by taking into account many factors, such as stability and efficiency, at the same time. Particularly for walking, state of the art techniques to approximate these sequences are based on reinforcement learning (RL). In this work we propose a multi-level system, where the same RL method is used first to learn the configuration of robot joints (poses) that allow it to stand with stability, and then in the second level, we find the sequence of poses that let it reach the furthest distance in the shortest time, while avoiding falling down and keeping a straight path. In order to evaluate this, we focus on measuring the time it takes for the robot to travel a certain distance. To our knowledge, this is the first work focusing both on speed and precision of the trajectory at the same time. We implement our model in a simulated environment using q-learning. We compare with the built-in walking modes of an NAO robot by improving normal-speed and enhancing robustness in fast-speed. The proposed model can be extended to other tasks and is independent of a particular robot model.

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“…The development of biped walking robots is one of the most challenging quests in the field of robotics [6]. A general controller architecture of the walker needs an agent to control stability ( Fig.…”

Section: Introductionmentioning

confidence: 99%

“…One of the major problems in biped gait is the definition of a stability criterion that can be used to generate trajectories that prevent the robot from falling during locomotion. The problem of finding a stability criterion begins with the question of defining stability in biped gait [6]. In this context, an operational definition of stability can be based on the ability of the robot to avoid falling.…”

Section: Introductionmentioning

confidence: 99%

Predicted Step Viability: a stability criterion for biped gait

Rossi

Parik-Americano

Simões

et al. 2019

J Braz. Soc. Mech. Sci. Eng.

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The formulation of a stability criterion is crucial to perform safe, versatile and efficient biped gaits for robots. We here present a stability criterion for non-cyclic gait synthesis, the Predicted Step Viability, inspired by human gait and N-Step Capturability. The Predicted Step Viability defines the constraints of the current step such that future steps will be able to guarantee convergence to a stable point in finite time. In this way, it is based on the prediction of future viable steps to ensure stability. The criterion was implemented using multiphase trajectory optimization on two biped models, the Compass Gait and the five-link model RABBIT. The Compass Gait was simulated with different model parameters and gait patterns including a random non-periodic one. The five-link model was tested with linear and random reference gait patterns. The Predicted Step Viability criterion successfully generated stable non-periodic gaits under a variety of conditions. Moreover, it is possible to prescribe any gait pattern completely uncoupled from the stability criterion. If it were impossible to follow the prescribed pattern without falling, the controller would give it up, maintaining stability.

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Walking with perturbations: a guide for biped humans and robots

Cited by 30 publications

References 377 publications

Effects of supraspinal feedback on human gait: rhythmic auditory distortion

Effects of supraspinal feedback on human gait: rhythmic auditory distortion

Learning an Efficient Gait Cycle of a Biped Robot Based on Reinforcement Learning and Artificial Neural Networks

Predicted Step Viability: a stability criterion for biped gait

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