A methodology for obtaining spatiotemporal information of the vehicles on bridges based on computer vision

Zhang, Bo; Zhou, Liming; Zhang, Jian

doi:10.1111/mice.12434

Cited by 70 publications

(45 citation statements)

References 36 publications

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“…Deep learning has also been used for vehicle spatial and temporal distribution monitoring in bridges. Zhang, Zhou, and Zhang (). proposed a Faster RCNN‐based method that can obtain the vehicle information automatically in real time.…”

Section: Introductionmentioning

confidence: 99%

Deep learning for data anomaly detection and data compression of a long‐span suspension bridge

Zhang

Noori

2019

Computer aided Civil Eng

Self Cite

188

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As intelligent sensing and sensor network systems have made progress and low-cost online structural health monitoring has become possible and widely implemented, large quantities of highly heterogeneous data can be acquired during the monitoring. This has resulted in exceeding the capacity of traditional data analytics techniques, especially in monitoring large-scale or critical civil structures. In particular, data storage has become a big challenge, hence, resulting in the emergence of data compression and reconstruction as a new area in structural health monitoring (SHM) of large infrastructure systems. SHM data generally include anomalies that can disturb structural analysis and assessment. The fundamental reasons for the abnormality of data are extremely complex. Therefore, reconstruction of the abnormal data is generally difficult and poses serious challenges to achieve high-accuracy after data has been compressed. Considering these significant challenges, in this paper, a novel deeplearning-enabled data compression and reconstruction framework is proposed that can be divided into two phases: (a) a one-dimensional Convolutional Neural Network (CNN) that extracts features directly from the input signals is designed to detect abnormal data with validated high accuracy; (b) a new SHM data compression and reconstruction method based on Autoencoder structure is further developed, which can recover the data with high-accuracy under such a low compression ratio. To validate the proposed approach, acceleration data from the SHM system of a long-span bridge in China are employed. In the abnormal data detection phase, the results show that the proposed method can detect anomaly with high accuracy. Subsequently, smaller reconstruction errors can be achieved even by using only 10% compression ratio for the normal data.

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Section: Introductionmentioning

confidence: 99%

Deep learning for data anomaly detection and data compression of a long‐span suspension bridge

Zhang

Noori

2019

Computer aided Civil Eng

Self Cite

188

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“…This part discusses about the challenges and opportunities in CV-SHM. Chen et al 219 : long-span bridge (load spectrum) Background subtracking + ZNCC template matching Chen et al 220 : long-span cable-stayed bridge (load spatio-temporal distribution) HOG feature + Random Forest + non-maximum suppression Pan et al 221 : road barrier (vehicle distribution and speed) Faster R-CNN Zhang et al 222 : long-span cable-stayed bridge Kalman filter tracking + WIM Dan et al 223 : highway bridge (load and spatio-temporal distribution) Adaptive thresholding + morphological reconstruction + WIM Micu et al 224 : long-span suspension bridge (vehicle load) CNN for classification + Faster R-CNN + Kalman filter tracking Zhou et al 225 : highway bridge (vehicle load range, spatio-temporal distribution, and tracking) CV: computer vision; DIC: digital image correlation; PIV: particle image velocimetry; R-CNN: region-based convolutional neural network; UIL: unit influence line; UIS: unit influence surface; ZNCC: zero-mean normalized cross-correlation; HOG: histogram of gradient; WIM: weigh-in-motion.…”

Section: Challenge and Opportunities In Real-life Practices Of Cv-shmmentioning

confidence: 99%

A review of computer vision–based structural health monitoring at local and global levels

Dong

Çatbaş

2020

Structural Health Monitoring

416

165

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Structural health monitoring at local and global levels using computer vision technologies has gained much attention in the structural health monitoring community in research and practice. Due to the computer vision technology application advantages such as non-contact, long distance, rapid, low cost and labor, and low interference to the daily operation of structures, it is promising to consider computer vision–structural health monitoring as a complement to the conventional structural health monitoring. This article presents a general overview of the concepts, approaches, and real-life practice of computer vision–structural health monitoring along with some relevant literature that is rapidly accumulating. The computer vision–structural health monitoring covered in this article at local level includes applications such as crack, spalling, delamination, rust, and loose bolt detection. At the global level, applications include displacement measurement, structural behavior analysis, vibration serviceability, modal identification, model updating, damage detection, cable force monitoring, load factor estimation, and structural identification using input–output information. The current research studies and applications of computer vision–structural health monitoring mainly focus on the implementation and integration of two-dimensional computer vision techniques to solve structural health monitoring problems and the projective geometry methods implemented are utilized to convert the three-dimensional problems into two-dimensional problems. This review mainly puts emphasis on two-dimensional computer vision–structural health monitoring applications. Subsequently, a brief review of representative developments of three-dimensional computer vision in the area of civil engineering is presented along with the challenges and opportunities of two-dimensional and three-dimensional computer vision–structural health monitoring. Finally, the article presents a forward look to the future of computer vision–structural health monitoring.

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“…Due to the computer vision technology, the image sensor has been applied in vehicle detection. Videos are obtained from the perspective of front or side view [ 17 , 18 ]. Image processing techniques and machine learning methods were used to detect the vehicles in continuous frames.…”

Section: Related Workmentioning

confidence: 99%

“…By applying CNN-based object detection methods, the vehicles were segmented from the background with class labels [ 27 , 28 , 29 ]. When calibrated with real world coordination systems, the spacing information of vehicles was accessed [ 18 ]. Combining the image processing-based clustering method, the axles were detected and thus the axle type was obtained [ 30 ].…”

Section: Related Workmentioning

confidence: 99%

Deep Learning Based Vehicle Detection and Classification Methodology Using Strain Sensors under Bridge Deck

Zhang

Dong

et al. 2020

Sensors

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Vehicle detection and classification have become important tasks for traffic monitoring, transportation management and pavement evaluation. Nowadays there are sensors to detect and classify the vehicles on road. However, on one hand, most sensors rely on direct contact measurement to detect the vehicles, which have to interrupt the traffic. On the other hand, complex road scenes produce much noise to consider when to process the signals. In this paper, a data-driven methodology for the detection and classification of vehicles using strain data is proposed. The sensors are well arranged under the bridge deck without traffic interruption. Next, a cascade pre-processing method is applied for vehicle detection to eliminate in-situ noise. Then, a neural network model is trained to identify the close-range following vehicles and separate them by Non-Maximum Suppression. Finally, a deep convolutional neural network is designed and trained to identify the vehicle types based on the axle group. The methodology was applied in a long-span bridge. Three strain sensors were installed beneath the bridge deck for a week. High robustness and accuracy were obtained by these algorithms. The methodology proposed in this paper is an adaptive and promising method for vehicle detection and classification under complex noise. It would serve as a supplement to current transportation systems and provide reliable data for management and decision-making.

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A methodology for obtaining spatiotemporal information of the vehicles on bridges based on computer vision

Cited by 70 publications

References 36 publications

Deep learning for data anomaly detection and data compression of a long‐span suspension bridge

Deep learning for data anomaly detection and data compression of a long‐span suspension bridge

A review of computer vision–based structural health monitoring at local and global levels

Deep Learning Based Vehicle Detection and Classification Methodology Using Strain Sensors under Bridge Deck

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