Railroad Crosstie Deflection Measurement via Ultrasonic Airborne Sonar and Computer Vision Techniques

ASNT 30th Research Symposium Conference Proceedings Pub Date : 1900-01-01 DOI:10.32548/rs.2022.011

A. Hosseinzadeh, D. Datta, F. L. di Scalea

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Abstract

A smart tie-tracking technology is proposed to measure the deflections of railroad crossties by means of non-contact ultrasonic testing in sonar mode and computer vision techniques. The sensing layout consists of an array of air-coupled capacitive transducers (in pulse-echo mode) and a high frame-rate camera, rigidly connected to the main frame of 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 machine learning-based image classification approach is developed to discriminate tie/ballast images and demarcate the crossties’ boundaries. The relative deflections of the identified crossties are eventually computed by tracking the arrival time of the reflected waves from the surfaces flagged as tie. Further inspection of the deflection profiles can reveal crossties with potential poor ballast support condition. The proposed ‘tie sonar’ system was prototyped and used to reconstruct the deflection profile of the crossties scanned during a series of test runs at the Rail Defect Testing Facility of UC San Diego as well as the BNSF yard in San Diego, CA.

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基于超声机载声纳和计算机视觉技术的铁路横向偏转测量

提出了一种利用声纳模式下的非接触式超声检测和计算机视觉技术测量铁路横轨挠度的智能跟踪技术。传感布局由空气耦合电容式换能器阵列(脉冲回波模式)和高帧率摄像机组成，牢固地连接在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，开发了一种基于机器学习的图像分类方法来区分压舱/压舱图像并划分交叉区域的边界。通过跟踪来自标记为领带的表面的反射波的到达时间，最终计算出已识别交叉的相对偏转。进一步检查挠度剖面可以发现具有潜在不良压载支撑条件的十字路口。在加州大学圣地亚哥分校的铁路缺陷测试设施以及加州圣地亚哥的BNSF船厂进行的一系列测试运行中，提出的“tie声纳”系统的原型被用于重建扫描的横向偏转剖面。

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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ASNT 30th Research Symposium Conference Proceedings

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