王振宇

个人信息Personal Information

副教授

硕士生导师

性别:男

毕业院校:吉林大学

学位:博士

所在单位:化工海洋与生命学院

学科:微电子学与固体电子学

办公地点:盘锦校区D07-303

电子邮箱:wangzhenyu@dlut.edu.cn

扫描关注

论文成果

当前位置: 中文主页 >> 科学研究 >> 论文成果

Pipeline leakage localization based on distributed FBG hoop strain measurements and support vector machine

点击次数:

论文类型:期刊论文

发表时间:2019-01-01

发表刊物:OPTIK

收录刊物:SCIE、Scopus

卷号:176

页面范围:1-13

ISSN号:0030-4026

关键字:FBG hoop strain sensor; Support vector regression (SVR); Pipeline leakage localization; Method of characteristics (MOC); Cross validation

摘要:Across the globe, pipelines help to carry all kinds of fluids across vast distances. Our prior work in fiber Bragg grating (FBG) hoop strain sensors are among the most recently reported technologies aimed at accomplishing the goal of continuous pipeline monitoring. Multiple hoop strain signals can be extracted from distributed FBG hoop strain sensors set along the pipeline to reflect leakage process. In this paper, we demonstrate the use of multiple, distributed FBG hoop strain sensors in cooperation with a support vector regression (SVR) to localize a leakage point along a model pipeline. Series of terminal hoop strain variations are extracted as the input variables to achieve multi regression analysis as to localize the leakage point. The parameters of different kernel functions are optimized through five-fold cross validation to obtain the highest leakage localization accuracy. The result shows that when taking radial basis kernel function (RBF) with optimized C and gamma values, the localization mean square error (MSE) reaches as low as 0.043. The anti-noise capability of the SVR model is evaluated through superimposing Gaussian white noise of different levels. From the simulation study, the average localization error is still acceptable (approximate to 500 m) even in 5% noise situation. The influence of hoop strain sensing points as input variables is also investigated. The system with more hoop strain sensing points shows more stable capability for different level noises. The results demonstrate feasibility and robustness of the SVR approach using multi-hoop strain measurements for pipeline leakage localization.