A cointegration approach for cable anomaly warning based on structural health monitoring data: An application to cable-stayed bridges

Fan, Ziyuan; Huang, Qiao; Ren, Yuan; Zhu, Zhihui; Xu, Xiang

doi:10.1177/1369433220924793

Cited by 27 publications

(15 citation statements)

References 41 publications

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“…The main cable and suspenders are the important load-bearing structural components in suspension bridges. The force changes in both main cable and suspenders will affect the service state of the bridge (Fan et al, 2020). The suspender tension monitoring of ICP3, ICP5, ICP8, ICP9 and ICP11 is as shown in Figure 18.…”

Section: Structural Health Monitoring Demonstrationmentioning

confidence: 99%

Structural health monitoring on Yangluo Yangtze River Bridge: Implementation and demonstration

Zhu

Ren

Wang

2022

Advances in Structural Engineering

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Long-span cable-supported bridge is one of crucial transportation infrastructures. Structural health monitoring (SHM) system that is used to assess structural service conditions and detect early damage has drawn a growing attention in engineering structural society. It provides a real-time monitoring of various structural changes under operational and extreme conditions. Yangluo Bridge over Yangtze River in Wuhan city of China is a 1280 m central span suspension bridge with an orthotropic steel box girder. Taking the SHM system of Yangluo Yangtze River Bridge as an example, this paper presents an implementation of SHM system on the bridge in terms of sensor layout, data acquisition strategy, data transmission, data processing, and abnormal alarm framework. With such an SHM system, the typical monitoring results are demonstrated such as operational environments, loadings, structural deformation, strains, dynamic properties, and structural responses. The SHM system of Yangluo Yangtze River Bridge is continuously gathering data and monitoring structural behavior. It is anticipated that it will provide either scientific or technological supports to the service comfort and safety of the bridge.

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Section: Structural Health Monitoring Demonstrationmentioning

confidence: 99%

Structural health monitoring on Yangluo Yangtze River Bridge: Implementation and demonstration

Zhu

Ren

Wang

2022

Advances in Structural Engineering

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“…In addition, the cointegration residual of the monitored cable force served as index to detect spikes. The details using cointegration techniques to detect anomalies are presented in our previous paper (Fan et al, 2020). The detection result is shown in Figure 17.…”

Section: Case Studymentioning

confidence: 99%

“…Zhu et al (2019) introduced the blind source separation to improve the performance of moving principal component analysis for anomaly detection by using strain data, where three cases were used to verify the effectiveness of the proposed methodology. Tome et al (2020) and Fan et al (2020) presented a strategy for early damage detection for a large cable-stayed bridge based on multivariate cointegration analysis and statistical process control, where the effects of environmental and operational variations were suppressed using cointegration analysis. Huang et al (2020) proposed a strain-based anomaly detection method for bridge main girders, where the correlation relationship between temperature and strain of the main girder was established.…”

Section: Introductionmentioning

confidence: 99%

“…Based on Figure16, anomaly event is detected with more than 95% confidence, however, the actual situation is that the anomaly detection is triggered by the spike signal, and the structure operated as usual.In addition, the cointegration residual of the monitored cable force served as index to detect spikes. The details using cointegration techniques to detect anomalies are presented in our previous paper(Fan et al, 2020). The detection result is shown in Figure17.…”

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confidence: 99%

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Probabilistic anomaly trend detection for cable-supported bridges using confidence interval estimation

Qian

Huang

et al. 2022

Advances in Structural Engineering

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To rate uncertainties within anomaly detection course for large span cable-supported bridges, a probabilistic approach is developed based on confidence interval estimation of extreme value analytics. First, raw signals from structural health monitoring system are pre-processed, including missing data imputation using moving time window mean imputation approach and thermal response separation through multi-resolution wavelet-based method. Then, an energy index is extracted from time domain signals to enhance robust of detection performance. A resampling-based method, namely the bootstrap, is adopted herein for confidence interval estimation. Four confidence levels are defined for the anomaly trend detection in this study, namely 95%, 80%, 50%, and 20%. Finally, the effectiveness of the proposed anomaly trend detection methodology is validated by using in-situ cable force measurements from the Nanjing Dashengguan Yangtze River Bridge. As a result, the four-level anomaly detection triggers are determined by using the confidence interval estimation based on cable force measurements in 2007, which are 58,671, 48,862, 42,499 and 39,035, respectively. Subsequently, three cases are presented, which are spike detection, overloading vehicle detection and snow disaster detection. Through the spike detection, it is verified that energy index is capable to tolerate signal spikes. Three overloading events are simulated to conduct overloading vehicle detections. As a result, the three overloading events are detected successfully associated with different confidences. Snow disaster is detected with a more than 80% confidence based on the field measurements during the snow storm time window.

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“…It can be seen that cable NJ21 is the longest cable (with a length of 354.53 m) of this bridge with almost the maximum force (designed as 3708 kN). Different from cable NA21, which is also a long cable but only in the side span, cable NJ21 directly supports the girder in the main span, so more attention has been paid to cable NJ21 by the bridge management department [43]. Hence, cable NJ21 in the third Nanjing Yangtze River Bridge was selected for a case study to validate the effectiveness of the proposed method.…”

Section: Estimation Of Temperature Effectmentioning

confidence: 99%

Estimation of Extreme Cable Forces of Cable‐Stayed Bridges Based on Monitoring Data and Random Vehicle Models

Ren

Zhu

Fan

et al. 2021

Advances in Civil Engineering

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For long-span cable-stayed bridges, cables serve as one of the most important components to guarantee structural integrity. Forces of stay cables indicate not only the performance of cables themselves but also the overall condition of bridges. In order to help stakeholders to make maintenance decisions, an extreme cable force estimation method was proposed based on cable force measurements and traffic data from the weighing system. First, raw monitoring data were preprocessed based on a median filtering to obtain usable cable force signals. The multiresolution wavelet method was used to extract traffic-induced force component from mixed signals. Then, a Monte Carlo-based random vehicle model was developed using traffic data from the weighing system. Based on field temperature measurements and simulation of traffic-induced effects, extreme cable forces with respect to vehicle loads and temperature effects were predicted by extreme value theory. The Generalized Pareto Distribution (GPD) was adopted to establish the probability distribution models of the daily maximum cable force. Then, the extreme value within a return period of 100 years was determined and compared with the design loading demand. Finally, the effectiveness of the proposed method was validated through a cable-stayed bridge in China. As a result, the low-frequency varying component of cable force response had positive correlation with environmental temperatures, and the extreme value of the predicted cable force under prospective traffic volumes was within limit interval value according to the design code. The conclusions can be utilized by bridge owners to make maintenance decisions.

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A cointegration approach for cable anomaly warning based on structural health monitoring data: An application to cable-stayed bridges

Cited by 27 publications

References 41 publications

Structural health monitoring on Yangluo Yangtze River Bridge: Implementation and demonstration

Structural health monitoring on Yangluo Yangtze River Bridge: Implementation and demonstration

Probabilistic anomaly trend detection for cable-supported bridges using confidence interval estimation

Estimation of Extreme Cable Forces of Cable‐Stayed Bridges Based on Monitoring Data and Random Vehicle Models

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