Train wheel-rail force collaborative calibration based on GNN-LSTM

Changfan Zhang , Zihao Yu , Lin Jia
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Abstract

Accurate wheel-rail force data serves as the cornerstone for analyzing the wheel-rail relationship. However, achieving continuous and precise measurement of this force remains a significant challenge in the field. This article introduces a calibration algorithm for the wheel-rail force that leverages graph neural networks and long short-term memory networks. Initially, a comprehensive wheel-rail force detection system for trains was constructed, encompassing two key components: an instrumented wheelset and a ground wheel-rail force measuring system. Subsequently, utilizing this system, two distinct datasets were acquired from the track inspection vehicle: instrumented wheelset data and ground wheel-rail force data, a feedforward neural network was employed to calibrate the instrumented wheelset data, referencing the ground wheel-rail force data. Furthermore, ground wheel-rail force data for the locomotive was obtained for the corresponding road section. This data was then integrated with the calibrated instrumented wheelset data from the track inspection vehicle. Leveraging the GNN-LSTM network, the article establishes a mapping relationship model between the wheel-rail force of the track inspection vehicle and the locomotive wheel-rail force. This model facilitates continuous measurement of locomotive wheel-rail forces across three typical scenarios: straight sections, long and steep downhill sections, and small curve radius sections.

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基于 GNN-LSTM 的列车轮轨力协同校准
精确的轮轨力数据是分析轮轨关系的基石。然而,实现对该力的连续、精确测量仍是该领域的一项重大挑战。本文介绍了一种利用图神经网络和长短期记忆网络的轮轨力校准算法。最初,我们为列车构建了一个全面的轮轨力检测系统,该系统包括两个关键组件:带仪器的轮组和地面轮轨力测量系统。随后,利用该系统从轨道检测车上获取了两个不同的数据集:仪器轮对数据和地面轮轨力数据,并采用前馈神经网络对仪器轮对数据进行校准,同时参考地面轮轨力数据。此外,还获得了机车在相应路段的地面轮轨力数据。然后将这些数据与轨道检测车的校准仪器轮对数据进行整合。文章利用 GNN-LSTM 网络,建立了轨道检测车轮轨力与机车轮轨力之间的映射关系模型。该模型有助于在三种典型情况下连续测量机车轮轨力:直线路段、长而陡的下坡路段和小半径曲线路段。
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