Optical-inertial system for railway track diagnostics

2014 DGON Inertial Sensors and Systems (ISS) Pub Date : 2014-09-01 DOI:10.1109/INERTIALSENSORS.2014.7049477

E. D. Bokhman, A. Boronachin, Y. Filatov, D. Larionov, L. Podgornaya, R. V. Shalymov, G. N. Zuzev

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引用次数: 22

Abstract

The paper presents the results of development of the Optical-lnertial System for Railway Track Diagnostics. It is demonstrated that in order to implement the solution at a speed of up to 430 kmph (used for example in South Korean high-speed train HEMU-430X, standing for High-Speed Electric Multiple Unit 430 km/h experimental) while satisfying the accuracy of 0.1...0.5 mm during measurement of longitudinal level, cross level, twist, curvature, rail profile, etc., it is needed to combine the optical scanners of the inner profile of the rail line with the strapdown inertial navigation system (SINS) in a single block. Supplying of odometer and Global navigation satellite system receiver (GNSS) into the system structure allows to determine measurement point position. Thanks to our a priori knowledge of the semipermanent nature of the railway track, and also to the fusion of the odometer data and satellite navigation system reception equipment data, it is possible to use fiber-optic gyros as the sensitive units of the SINS (both open-loop and closed-loop configurations of FOG can be used). The distinctive feature of the system's algorithm is that it solves both the navigation/orientation task (i.e. it fuses odometer data, satellite navigation system data and inertial navigation system data), and the task of measuring the inner surface profile of the rail line. The use of a sole odometer to localize the found rail flaws does not provide satisfactory results because of its errors. Integration of the odometer, SINS and GNSS receiver data offers highly accurate referencing of diagnostic results to the traversed track coordinate. Odometer readings are updated using the navigation system data. The system provides measuring of the track geometry and accurate localization of the measurement point using the geographical coordinates (latitude and longitude) and orientation parameters (roll, pitch and course angle). The possibility of using SINS based on fiber-optic gyros (FOG) for railway applications is considered in the article. Some practical results are given.

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用于铁路轨道诊断的光惯性系统

本文介绍了铁路轨道诊断光神经系统的研制成果。结果表明，为了实现该方案在高达430公里/小时的速度下(以韩国高速列车HEMU-430X为例，代表高速电动多单元430公里/小时实验)，同时在测量纵向水平，横向水平，扭转，曲率，轨道轮廓等时满足0.1…0.5 mm的精度。需要将轨道内轮廓的光学扫描器与捷联惯性导航系统(SINS)结合在一个模块中。在系统结构中提供里程表和全球导航卫星系统接收机(GNSS)，可以确定测量点的位置。由于我们对铁路轨道半永久性的先验知识，以及里程表数据和卫星导航系统接收设备数据的融合，可以使用光纤陀螺作为捷联惯导系统的敏感单元(既可以使用光纤陀螺的开环配置，也可以使用光纤陀螺的闭环配置)。该系统算法的显著特点是既解决了导航/定位任务(即融合里程表数据、卫星导航系统数据和惯性导航系统数据)，又解决了测量铁路线内表面轮廓的任务。使用单一的里程表来定位发现的轨道缺陷，由于其误差，不能提供令人满意的结果。里程表、捷联惯导系统和全球导航卫星系统接收器数据的集成，为经过的航迹坐标提供了高度精确的诊断结果参考。使用导航系统数据更新里程表读数。该系统使用地理坐标(纬度和经度)和方向参数(横摇、俯仰和航向角)提供轨道几何测量和精确定位测量点。本文讨论了基于光纤陀螺的捷联惯导系统在铁路上应用的可能性。给出了一些实际结果。

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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2014 DGON Inertial Sensors and Systems (ISS)

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