Modeling of the human vestibular system and integration in a simulator for the study of orientation and balance control

Actas de las XXXIX Jornadas de Automática, Badajoz, 5-7 de septiembre de 2018 Pub Date : 2020-03-06 DOI:10.17979/SPUDC.9788497497565.0636

Á. Canelo, I. T. Balsera, José Emilio Traver Becerra, B. M. V. Jara, Cristina Nuevo Gallardo

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引用次数: 3

Abstract

Biologically, the vestibular feedback is critical to the ability of human body to balance in different conditions. This paper presents a human-inspired orientation and balance control of a three degree- of-freedom (DOF) simulator that emulates a person sitting in a platform. In accordance with the role in humans, the control is essentially based on the vestibular system (VS), which regulates and stabilizes gaze during head motion, by means of modeling the behavior of the semicircular canals and otoliths in the presence of stimuli, i.e., linear and angular accelerations/velocities derived by the turns experienced by the robot head on the three Cartesian axes. The semicircular canal is used as the angular velocity sensor to perform the postural control of the robot. Simulation results in the MATLAB/Simulink environment are given to show that the orientation of the head in space (roll, pitch and yaw) can be successfully controlled by a proportional-integral-derivative (PID) with noise filter for each DOF.

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人体前庭系统的建模及在模拟器中的集成，用于方向和平衡控制的研究

在生物学上，前庭反馈对人体在不同条件下保持平衡的能力至关重要。本文提出了一种仿人姿态与平衡控制的三自由度平台仿真器。根据在人类中的作用，控制基本上是基于前庭系统(VS)，通过模拟半规管和耳石在刺激下的行为，即机器人头部在三个笛卡尔轴上的转弯所产生的线性和角加速度/速度，来调节和稳定头部运动时的凝视。采用半规管作为角速度传感器，对机器人进行姿态控制。在MATLAB/Simulink环境下的仿真结果表明，对每个自由度采用带噪声滤波器的比例-积分-导数(PID)可以成功地控制头部在空间中的方向(横摇、俯仰和偏航)。

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Actas de las XXXIX Jornadas de Automática, Badajoz, 5-7 de septiembre de 2018

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