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ZHANG Xingbin, YANG Xinguang, PAN Rong, FENG Zhangzhong, ZHU Jianguo, ZHANG Zhong. THEORETICAL RESEARCH AND APPLICATION OF THE INTELLIGENT MONITORING AND EVALUATION SYSTEM IN CIVIL ENGINEERING[J]. INDUSTRIAL CONSTRUCTION, 2021, 51(12): 102-106. doi: 10.13204/j.gyjzG21102024
Citation: ZHANG Xingbin, YANG Xinguang, PAN Rong, FENG Zhangzhong, ZHU Jianguo, ZHANG Zhong. THEORETICAL RESEARCH AND APPLICATION OF THE INTELLIGENT MONITORING AND EVALUATION SYSTEM IN CIVIL ENGINEERING[J]. INDUSTRIAL CONSTRUCTION, 2021, 51(12): 102-106. doi: 10.13204/j.gyjzG21102024

THEORETICAL RESEARCH AND APPLICATION OF THE INTELLIGENT MONITORING AND EVALUATION SYSTEM IN CIVIL ENGINEERING

doi: 10.13204/j.gyjzG21102024
  • Received Date: 2021-10-20
    Available Online: 2022-05-27
  • It is a complex project to realize intelligent monitoring and evaluation in civil engineering involving the intersection of multiple theories and technologies. An intelligent monitoring and evaluation system in civil engineering structures (MDCRS) was put forward, which could provide technical support for the safe operation and scientific management of large civil engineering and basic public facilities such as nuclear power generating stations, long-span bridges and industrial buildings. The system was mainly comprised of a monitoring system, a calculation and evaluation system, and a visualization system. Its main functions were as follows:implementing real-time and effective monitoring in engineering structure, processing and analyzing monitoring data, getting the inner physical nature of the structure by a fast algorithm and digital mapping tenchnique according to the specific characteristics of the structure, conducting simulations, analysis and research of various working conditions of the structure to assess structural safety, and displaying the structure state objectively and truthfully through the computer graphics display tenchnique. Two application instances were taken in the paper to illustrate the fact that the civil engineering intelligent monitoring and evaluation system could not only realize real-time and effective collection, transmission and storage of monitoring information, but also obtain the actual performance of the structure by a fast and scientific algorithm, further, could conduct a three-dimensional visual display and provide technical support for safe construction, operation, scientific management and decision-making in civil engineering.
  • [1]
    周智, 欧进萍.土木工程智能健康监测与诊断系统[J].传感器技术, 2001(11):1-4.
    [2]
    李宏男, 李东升.土木工程结构安全性评估、健康监测及诊断述评[J].地震工程与工程振动, 2002(3):82-90.
    [3]
    李惠, 鲍跃全, 李顺龙, 等.结构健康监测数据科学与工程[M].北京:科学出版社, 2016.
    [4]
    BAO Y Q, TANG Z Y, LI H, et al.Computer Vision and Deep Learning-Based Data Anomaly Detection Method for Structural Health Monitoring[J].Structural Health Monitoring, 2019, 18(2):401-421.
    [5]
    TANG Z Y, CHEN Z C, BAO Y Q, et al.Convolutional Neural Network-Based Data Anomaly Detection Method Using Multiple Information for Structural Health Monitoring[J].Structural Control and Health Monitoring, 2018, 26(11).https://doi.org/10.1002/stc.2296.
    [6]
    丁杨, 周双喜, 董晶亮, 等.人工智能方法在土木工程监测中的运用[J].材料导报, 2019, 33(增刊1):274-277.
    [7]
    周奎, 王琦, 刘卫东, 等.土木工程结构健康监测的研究进展综述[J].工业建筑, 2009, 39(3):96-102.
    [8]
    姜绍飞, 吴铭昊, 沈圣.大型结构健康监测的若干研究进展[C]//中国建筑科学研究院, 中国土木工程学会桥梁及结构工程分会空间结构委员会.第十五届空间结构学术会议论文集.北京:中国建筑科学研究院, 2014.
    [9]
    鲍跃全, 李惠.人工智能时代的土木工程[J].土木工程学报, 2019, 52(5):1-11.
    [10]
    许凯伟, 荣华, 杨璋, 等.压水堆核电机组安全壳结构自动化监测系统开发与应用[J].建筑结构, 2018, 48(16):111-113

    , 101.
    [11]
    TUIA D, VERRELST J, ALONSO L, et al.Multioutput Support Vector Regression for Remote Sensing Biophysical Parameter Estimation[J].IEEE Geoscience and Remote Sensing Letters, 2011, 8(4):804-808.
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