Generation of bipedal walking through interactions among the robot dynamics, the oscillator dynamics, and the environment: Stability characteristics of a five-link planar biped robot

Aoi, Shinya; Tsuchiya, Kazuo

doi:10.1007/s10514-010-9209-9

Cited by 26 publications

(22 citation statements)

References 67 publications

(68 reference statements)

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“…Although the phase resetting strategy is a powerful mechanism for improving gait stability [16,25], it is accompanied by modifications of the gait trajectory (phase-shift) with elevating and lowering patterns in response to external perturbations [4]. Thus, we characterize phase resetting as part of the above-mentioned requirement (ii), according to the classification proposed by Bruijn et al [2].…”

Section: Introductionmentioning

confidence: 99%

An intermittent control model of flexible human gait using a stable manifold of saddle-type unstable limit cycle dynamics

Suzuki

Kiyono

et al. 2014

J. R. Soc. Interface.

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Stability of human gait is the ability to maintain upright posture during walking against external perturbations. It is a complex process determined by a number of cross-related factors, including gait trajectory, joint impedance and neural control strategies. Here, we consider a control strategy that can achieve stable steady-state periodic gait while maintaining joint flexibility with the lowest possible joint impedance. To this end, we carried out a simulation study of a heel-toe footed biped model with hip, knee and ankle joints and a heavy head-arms-trunk element, working in the sagittal plane. For simplicity, the model assumes a periodic desired joint angle trajectory and joint torques generated by a set of feed-forward and proportional-derivative feedback controllers, whereby the joint impedance is parametrized by the feedback gains. We could show that a desired steady-state gait accompanied by the desired joint angle trajectory can be established as a stable limit cycle (LC) for the feedback controller with an appropriate set of large feedback gains. Moreover, as the feedback gains are decreased for lowering the joint stiffness, stability of the LC is lost only in a few dimensions, while leaving the remaining large number of dimensions quite stable: this means that the LC becomes saddle-type, with a low-dimensional unstable manifold and a high-dimensional stable manifold. Remarkably, the unstable manifold remains of low dimensionality even when the feedback gains are decreased far below the instability point. We then developed an intermittent neural feedback controller that is activated only for short periods of time at an optimal phase of each gait stride. We characterized the robustness of this design by showing that it can better stabilize the unstable LC with small feedback gains, leading to a flexible gait, and in particular we demonstrated that such an intermittent controller performs better if it drives the state point to the stable manifold, rather than directly to the LC. The proposed intermittent control strategy might have a high affinity for the inverted pendulum analogy of biped gait, providing a dynamic view of how the step-to-step transition from one pendular stance to the next can be achieved stably in a robust manner by a well-timed neural intervention that exploits the stable modes embedded in the unstable dynamics.

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Section: Introductionmentioning

confidence: 99%

An intermittent control model of flexible human gait using a stable manifold of saddle-type unstable limit cycle dynamics

Suzuki

Kiyono

et al. 2014

J. R. Soc. Interface.

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“…f balancing aRoll = −f balancing hRoll (3) i specifies the left or right leg, φ i is the phase of left or right CPG, and parameter A balancing specifies the amplitude of the lateral displacement motion. Leg flexion motion is performed by the unloaded leg.This is shown in eq.…”

Section: Cpg Based Control Architecturementioning

confidence: 99%

“…Most typical approaches when implementing CPGs for bipedal walking use phase oscillators that are fed into pattern generation layers [21], [1], [3], [25] or using neural oscillators [19].…”

Section: Introductionmentioning

confidence: 99%

Optimization of humanoid walking controller: Crossing the reality gap

Oliveira

Doncieux

Mouret

et al. 2013

2013 13th IEEE-RAS International Conference on Humanoid Robots (Humanoids)

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Abstract-Humanoid locomotion remains a challenge because of the inherent instability of such robotic platforms. Inspired from observations on animals, Central Pattern Generators have been proposed to support the generation of rhythmic patterns able to make a robot smoothly walk while requiring few computational power. Nevertheless, tuning such controllers is challenging, in particular because small irregularities in the walking pattern easily make the robot fall. Optimization algorithms can be used to tune them in simulation, but the transfer of such solutions to the real robot raises the reality gap problem, as a solution efficient in simulation may well be inefficient in reality. It is proposed here to use the transferability approach to solve this problem. Its principle is to learn a model of the transferability between simulation and reality while doing several evaluations on the real robot. This model is then used to estimate how well a controller will transfer onto the real robot and the optimization process tries to optimize it besides other cost functions related to locomotion and tested in simulation only. The approach has been applied to the DARWIN-OP robot.

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“…Compared with other robots (wheeled, crawler etc. ), the humanoid robot has the following characteristics: Discrete supporting foot, alternately touching the ground, walking stability under different circumstances, increased flexibility, more suitable to replace human work in harsh environments; Walking humanoid robot is a high level, strong coupling, nonlinear multi-degree of freedom system and a typical study in control theory and control engineering fields [1]; Walking humanoid robots have anthropomorphic mobile features and better affinities. They are more suitable for the task together with human; Research on walking gait of humanoid robot can promote the development of kinetic prosthetic and rehabilitation medicine; Research on walking humanoid robot could also promote the development of artificial intelligence, bionics, sensors, communications, computers and other related disciplines [2].…”

Section: Introductionmentioning

confidence: 99%

Influence of Biped Robot’s Walking Parameters on its Stability

Zhu¹,

Fu²

2014

TOAUTOCJ

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Abstract:In the biped robot's walking process, walking parameters have important influence on its stability. In this article we based on the ZMP criterion, using the relationship between ZMP and the support area to judge the walking stability. Calculate the size of stability margin to analyze the influence of parameters' change on stability. By programming in MATLAB and simulating in ADAMS, get the effects of gait parameters (step length, walk cycle, etc) on stability, put forward the reasonable selecting region of parameters, using genetic algorithm to get multiple sets of comprehensive parameters for analysis, the impact of each parameter on stability is identified. It may provide reference for the robot's gait planning later.

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Generation of bipedal walking through interactions among the robot dynamics, the oscillator dynamics, and the environment: Stability characteristics of a five-link planar biped robot

Cited by 26 publications

References 67 publications

An intermittent control model of flexible human gait using a stable manifold of saddle-type unstable limit cycle dynamics

An intermittent control model of flexible human gait using a stable manifold of saddle-type unstable limit cycle dynamics

Optimization of humanoid walking controller: Crossing the reality gap

Influence of Biped Robot’s Walking Parameters on its Stability

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