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基于卡尔曼滤波器的并置加速度、全球导航卫星系统和旋转数据融合用于6C运动跟踪

Kalman Filter-Based Fusion of Collocated Acceleration, GNSS and Rotation Data for 6C Motion Tracking.

作者信息

Rossi Yara, Tatsis Konstantinos, Awadaljeed Mudathir, Arbogast Konstantin, Chatzi Eleni, Rothacher Markus, Clinton John

机构信息

Institute of Geodesy and Photogrammetry, ETH Zurich, Robert-Gnehm Weg 15, CH-8093 Zurich, Switzerland.

Swiss Seismological Service, ETH Zurich, Sonneggstrasse 5, CH-8092 Zurich, Switzerland.

出版信息

Sensors (Basel). 2021 Feb 23;21(4):1543. doi: 10.3390/s21041543.

DOI:10.3390/s21041543
PMID:33672219
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7926865/
Abstract

The ground motion of an earthquake or the ambient motion of a large engineered structure not only has translational motion, but it also includes rotation around all three axes. No current sensor can record all six components, while the fusion of individual instruments that could provide such recordings, such as accelerometers or Global Navigation Satellite System (GNSS) receivers, and rotational sensors, is non-trivial. We propose achieving such a fusion via a six-component (6C) Kalman filter (KF) that is suitable for structural monitoring applications, as well as earthquake monitoring. In order to develop and validate this methodology, we have set up an experimental case study, relying on the use of an industrial six-axis robot arm, on which the instruments are mounted. The robot simulates the structural motion resulting atop a wind-excited wind turbine tower. The quality of the 6C KF reconstruction is assessed by comparing the estimated response to the feedback system of the robot, which performed the experiments. The fusion of rotational information yields significant improvement for both the acceleration recordings but also the GNSS positions, as evidenced via the substantial reduction of the RMSE, expressed as the difference between the KF predictions and robot feedback. This work puts forth, for the first time, a KF-based fusion for all six motion components, validated against a high-precision ground truth measurement. The proposed filter formulation is able to exploit the strengths of each instrument and recover more precise motion estimates that can be exploited for multiple purposes.

摘要

地震的地面运动或大型工程结构的环境运动不仅具有平动,还包括绕所有三个轴的转动。目前没有传感器能够记录所有六个分量,而将能够提供此类记录的单个仪器(如加速度计或全球导航卫星系统(GNSS)接收器)与旋转传感器进行融合并非易事。我们建议通过适用于结构监测应用以及地震监测的六分量(6C)卡尔曼滤波器(KF)来实现这种融合。为了开发和验证这种方法,我们建立了一个实验案例研究,依赖于使用一个安装了仪器的工业六轴机器人手臂。该机器人模拟风力激励的风力涡轮机塔顶产生的结构运动。通过将估计响应与进行实验的机器人反馈系统进行比较,评估6C KF重建的质量。旋转信息的融合对于加速度记录以及GNSS位置都有显著改善,通过均方根误差(RMSE)的大幅降低得以证明,RMSE表示为KF预测与机器人反馈之间的差异。这项工作首次提出了基于KF的所有六个运动分量的融合,并针对高精度的地面真实测量进行了验证。所提出的滤波器公式能够利用每个仪器的优势,恢复更精确的运动估计,可用于多种目的。

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