A transfer alignment algorithm based on combined double-time observation of velocity and attitude

Guangrun Sheng, Xixiang Liu, Zixuan Wang, Wenhao Pu, Xiaoqiang Wu, Xiaoshuang Ma
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Abstract

Purpose

This paper aims to present a novel transfer alignment method based on combined double-time observations with velocity and attitude for ships’ poor maneuverability to address the system errors introduced by flexural deformation and installing which are difficult to calibrate.

Design/methodology/approach

Based on velocity and attitude matching, redesigning and deducing Kalman filter model by combining double-time observation. By introducing the sampling of the previous update cycle of the strapdown inertial navigation system (SINS), current observation subtracts previous observation are used as measurements for transfer alignment filter, system error in measurement introduced by deformation and installing can be effectively removed.

Findings

The results of simulations and turntable tests show that when there is a system error, the proposed method can improve alignment accuracy, shorten the alignment process and not require any active maneuvers or additional sensor equipment.

Originality/value

Calibrating those deformations and installing errors during transfer alignment need special maneuvers along different axes, which is difficult to fulfill for ships’ poor maneuverability. Without additional sensor equipment and active maneuvers, the system errors in attitude measurement can be eliminated by the proposed algorithms, meanwhile improving the accuracy of the shipboard SINS transfer alignment.

基于速度和姿态双时间联合观测的传递对准算法
目的针对船舶机动性能差的特点,提出一种基于航速和姿态双时间联合观测的传递对准方法,以解决船舶弯曲变形和安装带来的难以标定的系统误差。基于速度和姿态匹配,结合双时间观测,重新设计并推导卡尔曼滤波模型。通过引入捷联惯导系统前一更新周期的采样,以当前观测值减去前一观测值作为传递对准滤波器的测量值,有效地消除了由变形和安装引起的测量系统误差。仿真和转台试验结果表明,在存在系统误差的情况下,该方法可以提高对准精度,缩短对准过程,且不需要任何主动机动或额外的传感器设备。在传递对准过程中,这些变形和安装误差的校正需要沿着不同的轴线进行特殊的机动,而由于船舶的操纵性较差,这很难实现。该算法在不需要额外传感器设备和主动机动的情况下,消除了系统姿态测量误差,同时提高了舰载捷联惯导传递对准精度。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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