A Bidirectional Long Short Term Memory Approach for Infrastructure
Health Monitoring Using On-board Vibration Response
Reference
R.R. Samani,
A. Núñez, and
B. De Schutter,
"A Bidirectional Long Short Term Memory Approach for Infrastructure
Health Monitoring Using On-board Vibration Response," Proceedings of the 104th Annual Meeting of the
Transportation Research Board, Washington, DC, 16 pp., Jan.
2025. Paper TRBAM-25-04560.
Abstract
The growing volume of available infrastructural monitoring data
enables the development of powerful data-driven approaches to estimate
infrastructure health conditions using direct measurements. This paper
proposes a deep learning methodology to estimate infrastructure
physical parameters, such as railway track stiffness, using drive-by
vibration response signals. The proposed method employs a Long
Short-term Memory (LSTM) feature extractor accounting for temporal
dependencies in the feature extraction phase, and a bidirectional Long
Short-term Memory (BiLSTM) networks to leverage bidirectional temporal
dependencies in both the forward and backward paths of the drive-by
vibration response in condition estimation phase. Additionally, a
framing approach is employed to enhance the resolution of the
monitoring task to the beam level by segmenting the vibration signal
into frames equal to the distance between individual beams, centering
the frames over the beam nodes. The proposed LSTM-BiLSTM model offers
a versatile tool for various bridge and railway infrastructure
conditions monitoring using direct drive-by vibration response
measurements. The results demonstrate the potential of incorporating
temporal analysis in the feature extraction phase and emphasize the
pivotal role of bidirectional temporal information in infrastructure
health condition estimation. The proposed methodology can accurately
and automatically estimate railway track stiffness and identify local
stiffness reductions in the presence of noise using drive-by
measurements. An illustrative case study of vehicle-track interaction
simulation is used to demonstrate the performance of the proposed
model, achieving a maximum mean absolute percentage error of 1.7% and
0.7% in estimating railpad and ballast stiffness, respectively.
Bibtex entry
@inproceedings{SamNun:25-003,
author={R.R. Samani and A. N{\'{u}}{\~{n}}ez and B. {D}e Schutter},
title={A Bidirectional Long Short Term Memory Approach for Infrastructure Health
Monitoring Using On-board Vibration Response},
booktitle={Proceedings of the 104th Annual Meeting of the Transportation
Research Board},
address={Washington, DC},
month=jan,
year={2025},
note={Paper TRBAM-25-04560}
}
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Last update: February 21, 2026.