Tilt estimator for 3D non-rigid pendulum based on a tri-axial accelerometer and gyrometer

M. Benallegue, A. Benallegue, Y. Chitour
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引用次数: 10

Abstract

The paper presents a new observer for tilt estimation of a 3-D non-rigid pendulum. The system can be seen as a multibody robot attached to the environment with a ball joint for which there is no sensor. The estimation of tilt, i.e. roll and pitch angles, is mandatory for balance control for a humanoid robot and all tasks requiring verticality. Our method obtains tilt estimations using joints encoders and inertial measurements given by an IMU equipped with triaxial accelerometer and gyrometer mounted in any body of the robot. The estimator takes profit from the kinematic coupling resulting from the pivot constraint and uses the entire signal of accelerometer including linear accelerations. Almost Global Asymptotic convergence of the estimation errors is proven together with local exponential stability. The performance of the proposed observer is illustrated by simulations.
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基于三轴加速度计和陀螺仪的三维非刚性摆倾斜估计器
提出了一种用于三维非刚性摆倾斜估计的新观测器。该系统可以被看作是一个多体机器人,附着在没有传感器的球形关节上。估计倾斜,即滚转角和俯仰角,是必要的平衡控制的人形机器人和所有任务需要垂直。我们的方法利用关节编码器和由安装在机器人任何身体上的配有三轴加速度计和陀螺仪的IMU给出的惯性测量来获得倾斜估计。该估计器利用了由枢轴约束引起的运动耦合,并使用了包括线性加速度在内的加速度计的整个信号。证明了估计误差的几乎全局渐近收敛性和局部指数稳定性。仿真结果表明了该观测器的性能。
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