Faulty data detection and classification for bridge structural health monitoring via statistical and deep‐learning approach

Jian, Xudong; Zhong, Huaqiang; Xia, Ye; Sun, Lijun

doi:10.1002/stc.2824

Cited by 18 publications

(8 citation statements)

References 38 publications

(15 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Anomaly identification for vibration signals can be disposed as time series classification, for which the effectiveness of one-dimensional (1D) CNN has been proved by some researchers (Jian et al 2021;Zhang and Lei 2021). Visualizing the time signals into images is an effective approach to leverage two-dimensional (2D) CNN for this mission.…”

Section: Anomaly Identificationmentioning

confidence: 99%

“…Visualizing the time signals into images is an effective approach to leverage two-dimensional (2D) CNN for this mission. And drawing their curves directly is the most frequently adopted method, while other feature engineering approaches, like the spectrogram analysis, the probability density function and so on, were also employed to enhance the network's robustness (Jian et al 2021;Shajihan et al 2022). For example, Tang et al (2019) visualized time series data in time and frequency domain and stacked them as a single dual-channel image before it was inputted into a 2D CNN to classify data anomalies (see Fig.…”

Section: Anomaly Identificationmentioning

confidence: 99%

See 1 more Smart Citation

The application of deep learning in bridge health monitoring: a literature review

Zhang

Wang

et al. 2022

ABEN

View full text Add to dashboard Cite

Along with the advancement in sensing and communication technologies, the explosion in the measurement data collected by structural health monitoring (SHM) systems installed in bridges brings both opportunities and challenges to the engineering community for the SHM of bridges. Deep learning (DL), based on deep neural networks and equipped with high-end computer resources, provides a promising way of using big measurement data to address the problem and has made remarkable successes in recent years. This paper focuses on the review of the recent application of DL in SHM, particularly damage detection, and provides readers with an overall understanding of the missions faced by the SHM of the bridges. The general studies of DL in vibration-based SHM and vision-based SHM are respectively reviewed first. The applications of DL to some real bridges are then commented. A summary of limitations and prospects in the DL application for bridge health monitoring is finally given.

show abstract

Section: Anomaly Identificationmentioning

confidence: 99%

Section: Anomaly Identificationmentioning

confidence: 99%

The application of deep learning in bridge health monitoring: a literature review

Zhang

Wang

et al. 2022

ABEN

View full text Add to dashboard Cite

show abstract

“…Thus, for a training sample ranging over 1-h values, the feature extracted is represented by a 9 Â 60 matrix. The features are listed as follows: (1) mean value, (2) maximum value difference, (3) standard deviation, (4) root mean square level, (5) difference between the maximum and minimum, (6) maximum value divided by the 80th percentile, (7) mean value divided by the amplitude, (8) mean value divided by the 80th percentile, and ( 9) natural frequency estimated by Welch's power spectral density. The attempts in feature selection, including data dimensionality reduction and feature selection based on statistical indicators, and the construction of data set toward solving the above problems in deep learning can provide a certain reference for the classification tasks for deep learning.…”

Section: The Characteristics Of Each Anomaly Typementioning

confidence: 99%

“…The process of performing data anomaly identification and locating and repairing anomalous data segments is called data cleansing 6 . Therefore, data cleaning is the basic prerequisite for data mining and analysis by the monitoring system 7 …”

Section: Introductionmentioning

confidence: 99%

“…6 Therefore, data cleaning is the basic prerequisite for data mining and analysis by the monitoring system. 7 Data cleansing consists of two parts: data anomaly identification and data repair. For anomaly identification, traditional methods are mainly based on a statistical analysis of long-term historical data by finding sensitivity indicators and setting reasonable thresholds for specific indicators.…”

mentioning

confidence: 99%

See 1 more Smart Citation

A two‐stage data cleansing method for bridge global positioning system monitoring data based on bi‐direction long and short term memory anomaly identification and conditional generative adversarial networks data repair

Yang

Jiang

Zhao

et al. 2022

Structural Contr & Hlth

View full text Add to dashboard Cite

Summary Data cleansing is an essential approach for improving data quality. Therefore, it is the key to avoiding the false alarm of the monitoring system due to the anomaly of the data itself. Data cleansing consists of two parts: anomaly identification and anomaly repair. However, current research on data cleansing has mainly focused on anomaly identification and lacks efficient data repair methods. The key to data repair lies in sensor correlation models based on mapping relationships between sensors. To obtain a good inter‐sensor relationship model, it is first necessary to exclude anomalous data from the training data set used for modeling. Therefore, a two‐stage data cleansing framework for collaborative multi‐sensor repair is proposed. First, based on the analysis of anomalous features of GPS data, a bidirectional long‐ and short‐term memory (Bi‐LSTM) neural network model is adopted for data anomalies classification and localization. As a result, the data segment to be repaired is determined. Then, on the basis of all sensor data in the time range of the day before the target repair data segment, the data set for data repair is constructed by excluding the anomaly data segments in the data set with the help of the above anomaly identification results. Then, a conditional generation adversarial network (CGAN) is proposed to achieve data repair. Experimental validation shows that the two‐stage data cleansing method of identification followed by repair can accurately identify and repair GPS anomalies. Finally, several factors affecting the repair effect are discussed.

show abstract

Research on mapping relationship between environmental load and vibration response of bridge structure based onstructural health monitoringdata

Qiao,

Ding,

Zhou

et al. 2023

Engineering Reports

View full text Add to dashboard Cite

With the increasing lifespan of bridges, various forms of deterioration will inevitably occur. The bridge health monitoring system enables direct monitoring of the loads (such as wind, temperature, and vehicles) experienced by the bridge during operation, as well as the corresponding vibration response of the bridge structure (including main beam deformation, tower top displacement, cable acceleration, etc.). These data provide valuable insights into the safety and durability of the bridge during its operational lifetime. However, the challenge lies in extracting meaningful information from the vast amount of collected data. This article focuses on the Fuyu Bridge as a research case and analyzes the variations in environmental factors, such as temperature, humidity, wind load, and structural vibration responses (main beam and cable), obtained from the Fuyu Bridge's structural health monitoring system. It also conducts a structural safety assessment during the operational period of the bridge. Furthermore, the research explores the relationship between environmental factors, load effects, and structural response to establish a foundation for future structural safety assessments of the Fuyu Bridge during its operational period. For instance, changes in environmental factors or load effects can be used to predict structural responses. Additionally, this study provides access to the structural health monitoring data of the Fuyu Bridge, facilitating data‐driven research for other scholars in the field.

show abstract

Faulty data detection and classification for bridge structural health monitoring via statistical and deep‐learning approach

Cited by 18 publications

References 38 publications

The application of deep learning in bridge health monitoring: a literature review

The application of deep learning in bridge health monitoring: a literature review

A two‐stage data cleansing method for bridge global positioning system monitoring data based on bi‐direction long and short term memory anomaly identification and conditional generative adversarial networks data repair

Research on mapping relationship between environmental load and vibration response of bridge structure based onstructural health monitoringdata

Contact Info

Product

Resources

About