Alessandra De Angelis, Antonio Bilotta, Maria Rosaria Pecce, Andrea Pollastro, Roberto Prevete
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Indeed, external restraints (i) affect dynamic properties and, thus, the action experienced during an earthquake, and (ii) influence the capacity to detach the component before failure from the bearing structure (e.g., an infill wall connected to the main structural frame, or equipment connected to secondary structural members such as floors). The authors, therefore, conducted environmental vibration tests of an infill wall and refined a finite element model to simulate typical damage scenarios to be implemented on the wall. Selected damage scenarios were then artificially realized on the existing infill and further ambient vibration tests were performed to measure the accelerations for each of them. Finally, the authors used these accelerations to detect the damage by means of established OMA, as well as innovative machine learning techniques. The results showed that convolutional variational autoencoders (CVAE), coupled with a one-class support vector machine (OC-SVM), identified the anomaly even when the OMA exhibited limited effectiveness. 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引用次数: 0
摘要
地震发生后,非结构性部件的失效是地震造成的损失中最昂贵的一种,而且还可能造成危及生命的后果,尤其是在设施非常拥挤的公共建筑中,因为暴露程度高,风险也相应增加。对现有非结构部件的评估尤为复杂,因为必须进行深入的现场调查,才能发现存在的缺陷或损坏。这个问题涉及各种材料(如玻璃和砖石)制成的内部和外部隔墙,以及建筑(建筑、工业和基础设施)中的设备和设施。确定这些组件的边界条件至关重要。事实上,外部约束(i)会影响动态特性,进而影响地震时的作用,(ii)会影响部件在失效前从承重结构中脱离的能力(例如,与主结构框架相连的填充墙,或与楼板等次要结构部件相连的设备)。因此,作者对填充墙进行了环境振动测试,并改进了有限元模型,以模拟填充墙可能出现的典型损坏情况。然后,在现有的填充墙上人为地实现了选定的损坏情况,并进行了进一步的环境振动测试,以测量每种情况的加速度。最后,作者利用这些加速度,通过成熟的 OMA 以及创新的机器学习技术来检测损坏情况。结果表明,卷积变异自动编码器(CVAE)与单类支持向量机(OC-SVM)相结合,即使在 OMA 的有效性有限的情况下也能识别出异常。此外,机器学习程序最大限度地减少了损坏检测过程中的人工干预。
Dynamic identification methods and artificial intelligence algorithms for damage detection of masonry infills
The failure of non-structural components after an earthquake is among the most expensive earthquake-incurred damage, and may also have life-threatening consequences, especially in public buildings with very crowded facilities, because exposition is high and the risk increases accordingly. The assessment of existing non-structural components is particularly complex because in-depth in situ investigation is necessary to detect the presence of deficiencies or damage. This problem concerns interior and exterior partitions made of various materials (e.g., glass and masonry), as well as equipment and facilities in construction (building, industry, and infrastructure). Defining the boundary conditions of these components is of paramount importance. Indeed, external restraints (i) affect dynamic properties and, thus, the action experienced during an earthquake, and (ii) influence the capacity to detach the component before failure from the bearing structure (e.g., an infill wall connected to the main structural frame, or equipment connected to secondary structural members such as floors). The authors, therefore, conducted environmental vibration tests of an infill wall and refined a finite element model to simulate typical damage scenarios to be implemented on the wall. Selected damage scenarios were then artificially realized on the existing infill and further ambient vibration tests were performed to measure the accelerations for each of them. Finally, the authors used these accelerations to detect the damage by means of established OMA, as well as innovative machine learning techniques. The results showed that convolutional variational autoencoders (CVAE), coupled with a one-class support vector machine (OC-SVM), identified the anomaly even when the OMA exhibited limited effectiveness. Moreover, the machine learning procedure minimizes human interaction during the damage detection process.
期刊介绍:
The Journal of Civil Structural Health Monitoring (JCSHM) publishes articles to advance the understanding and the application of health monitoring methods for the condition assessment and management of civil infrastructure systems.
JCSHM serves as a focal point for sharing knowledge and experience in technologies impacting the discipline of Civionics and Civil Structural Health Monitoring, especially in terms of load capacity ratings and service life estimation.