In-Motion Railroad Tie Deflection Measurement via Ultrasonic Airborne Sonar and Computer Vision Techniques

IF 1 4区材料科学 Q3 MATERIALS SCIENCE, CHARACTERIZATION & TESTING Research in Nondestructive Evaluation Pub Date : 2022-11-03 DOI:10.1080/09349847.2022.2136808

Ali Zare Hosseinzadeh, D. Datta, F. Lanza di Scalea

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引用次数: 2

Abstract

ABSTRACT It is known in the railroad maintenance engineering community that the deflection of railroad ties is an indicator of the quality of the tie–ballast interface, whose deterioration may cause dangerous train derailments. A new technology is proposed to reconstruct the full-field deflection profile of railroad ties in-motion by means of non-contact ultrasonic testing and computer vision techniques. The sensing layout consists of an array of air-coupled capacitive transducers (operated in pulse-echo sonar-based ranging mode) and a high frame-rate camera, rigidly connected to the main frame of a moving train car. The acquisition system is programmed such that the synchronized waveforms and images are collected and saved as train car moves. In the processing stage, a supervised machine learning-based image classification approach is developed to demarcate the tie boundaries. For this purpose, the Speeded-Up Robust Features (SURF) and Bag of Visual Words (BOVW) algorithms are employed to encode images into condensed feature vectors, which are subsequently fed into the Support Vector Machine (SVM) to train a classifier. The relative deflections of the identified ties are eventually computed by tracking the time-of-flight of the reflected waves from the surfaces flagged as tie. An image processing technique is also developed to estimate the spatial resolution of the tracking system, required to reconstruct the full-field deflection profile of the scanned ties. The importance of such a technique is stressed if the test run is performed without any dedicated positioning system. The proposed ‘tie sonar’ system was prototyped and used to reconstruct the deflection profile of the ties scanned during a series of test runs conducted at slow (walking) speed at the Rail Defect Testing Facility (RDTF) of UC San Diego as well as a BNSF yard in San Diego, CA, with a realistic train load. Further developments of this system should include a performance evaluation at higher speeds (e.g., revenue speed).

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基于超声机载声纳和计算机视觉技术的铁路动铁挠度测量

摘要在铁路维修工程界，众所周知，钢轨的挠度是衡量系碴界面质量的一个指标，其恶化可能会导致危险的列车脱轨。提出了一种利用非接触式超声检测和计算机视觉技术重建运动中铁路枕木全场挠度曲线的新技术。传感布局由一组空气耦合电容式换能器(以脉冲回波声纳为基础的测距模式运行)和一个高帧率摄像机组成，牢固地连接到移动的火车车厢的主框架上。对采集系统进行了编程，使同步波形和图像在列车行驶时被采集和保存。在处理阶段，提出了一种基于监督机器学习的图像分类方法来划分边界。为此，采用加速鲁棒特征(SURF)和视觉词包(BOVW)算法将图像编码为浓缩特征向量，然后将其输入支持向量机(SVM)来训练分类器。通过跟踪从标记为领带的表面反射波的飞行时间，最终计算出已识别的领带的相对偏转。此外，还开发了一种图像处理技术，用于估计跟踪系统的空间分辨率，以重建扫描连杆的全场偏转轮廓。如果在没有任何专用定位系统的情况下进行测试，则强调了这种技术的重要性。在加州大学圣地亚哥分校(UC San Diego)的铁路缺陷测试设施(RDTF)和加州圣地亚哥的BNSF车场进行的一系列慢速(步行)测试中，提出的“tie声纳”系统原型用于重建扫描的tie偏转轮廓，并具有真实的列车负载。该系统的进一步发展应包括以更高的速度(例如，收入速度)进行业绩评价。

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来源期刊

Research in Nondestructive Evaluation 工程技术-材料科学：表征与测试

CiteScore

2.30

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Research in Nondestructive Evaluation® is the archival research journal of the American Society for Nondestructive Testing, Inc. RNDE® contains the results of original research in all areas of nondestructive evaluation (NDE). The journal covers experimental and theoretical investigations dealing with the scientific and engineering bases of NDE, its measurement and methodology, and a wide range of applications to materials and structures that relate to the entire life cycle, from manufacture to use and retirement. Illustrative topics include advances in the underlying science of acoustic, thermal, electrical, magnetic, optical and ionizing radiation techniques and their applications to NDE problems. These problems include the nondestructive characterization of a wide variety of material properties and their degradation in service, nonintrusive sensors for monitoring manufacturing and materials processes, new techniques and combinations of techniques for detecting and characterizing hidden discontinuities and distributed damage in materials, standardization concepts and quantitative approaches for advanced NDE techniques, and long-term continuous monitoring of structures and assemblies. Of particular interest is research which elucidates how to evaluate the effects of imperfect material condition, as quantified by nondestructive measurement, on the functional performance.