仪器科学与技术学科
基本信息
性别:男 || 政治面貌:党员 || 现任职称:副教授
最后学历: 博士 || 最后学位:工学博士 || 获学位单位:华北电力大学
是否留学:是 || 留学国别:英国 || 留学时间:2015-2016
联系方式: || 邮箱:cuixiwang@bistu.edu.cn || 通讯地址:北京海淀区清河小营东路12号
导师信息
硕导/博导:硕导 || 批硕/博导时间:2021.12
在读硕士:5人 || 毕业硕士:0人
所属院系、学科及研究方向
所属学院:威廉体育williamhill
所属学科:测控技术与仪器
研究方向1:信号检测与信息处理
研究方向2:埋地物体声波感知和探测成像
研究方向3:设备故障诊断、声纹识别、状态检测、目标源定位
参加学术团体
中国声学学会
中国人工智能学会
工作简历
威廉希尔WilliamHill官方网站
中国科学院声学研究所
承担教学任务
本科课程:信号与系统
承担科研项目情况
[1] 国家自然科学基金青年基金, 12104060,主持;
[2] 北京市自然科学基金青年基金, 1214025,主持;
[3] 声场声信息国家重点实验室开放课题,2024,主持;
[4] 北京市教委科研计划项目, KM202111232021,主持;
[5] 国家重点实验室开放课题研究基金,2022,主持;
[6] 中央高校基本科研业务专项资金,2014XS40,主持;
[7] 国家自然科学基金面上项目,11974376,参加;
[8] 国家自然科学基金面上项目,11874389,参加
主要论文目录
发表的SCI期刊论文如下,其中*表示通讯作者。
[1] X. Cui, Y. Gao, J. Muggelton, Y. Liu. Superimposed imaging of acoustic wave reflections for the detection of underground nonmetallic pipelines. Mechanical Systems and Signal Processing, 2024, 209: 111127. (SCI,一区Top)
[2] X. Cui, Y. Gao, X. Han. On the mixed acoustic and vibration sensors for the cross-correlation analysis of pipe leakage signals. Applied Acoustics, 2024, 216: 109798. (SCI)
[3] X. Cui, Z. Yan, Y. Gao, X. Cheng. Active acoustic excitation method for leak detection of buried gas pipelines based on cavity resonance reflection. IEEE Sensors Journal, Accepted, 2024. (SCI)
[4] X. Cui, Y. Gao, Y. Ma, F. Liu, H. Wang. Time delay estimation using cascaded LMS filters fused by correlation coefficient for pipeline leak localization. Mechanical Systems and Signal Processing, 2023, 199: 110500. (SCI,一区Top)
[5] Z. Yan, X. Cui*, Y. Gao. Acoustic injection method based on weak echo signals for leak detection and localization in gas pipelines. Applied Acoustics, 2023, 211: 109577. (SCI)
[6] X. Cui, Y. Gao, Y. Ma, Y. Liu, B. Jin. Variable step normalized LMS adaptive filter for leak localization in water-filled plastic pipes. IEEE Transactions on Instrumentation and Measurement, 2022, 71: 9600511. (SCI)
[7] X. Han, W. Cao, X. Cui*, Y. Gao. Plastic Pipeline Leak Localization Based on Wavelet Packet Decomposition and Higher Order Cumulants. IEEE Transactions on Instrumentation and Measurement. 2022, 71, 3520911. (SCI)
[8] X. Han, J. Liu, X. Cui*, Y. Gao, Z. Yan. Identification of Pipeline Leak Sizes Based on Chaos-Grey Wolf-Support Vector Machine. IEEE Sensors Journal, 2023, 23(19): 23179-23190. (SCI)
[9] H. Ji, X. Cui*, Y. Gao, X. Ge. 3-D ultrasonic localization of transformer patrol robot based on EMD and PHAT-beta algorithms. IEEE Transactions on Instrumentation and Measurement, 2021, 70, 9004810. (SCI)
[10] H. Ji, X. Cui*, W. Ren, et al. Visual inspection for transformer insulation defects by a patrol robot fish based on deep learning. IET Science, Measurement & Technology, 2021, 15: 606-618. (SCI)
[11] X. Cui, Y. Yan, Y. Hu, M. Guo. Performance comparison of acoustic emission sensor arrays in different topologies for the localization of gas leakage on a flat-surface structure. Sensors and Actuators A-Physical, 2019, 300, 111659. (SCI)
[12] X. Han, S. Zhao, X. Cui*, Y. Yan. Localization of CO2 Gas Leakages Using Acoustic Emission Multi-sensor Fusion Based on Wavelet-RBFN Modeling. Measurement Science and Technology, 2019, 30, 085007. (SCI)
[13] X. Cui, Y. Yan, Y. Ma, L. Ma, X. Han. Localization of CO2 Leakage from Transportation Pipelines Through Low Frequency Acoustic Emission Detection. Sensors and Actuators A-Physical, 2016, 237: 107-118. (SCI)
[14] X. Cui, Y. Yan, M. Guo, X. Han, Y. Hu. Localization of CO2 Leakage from a Circular Hole on a Flat-Surface Structure Using a Circular Acoustic Emission Sensor Array. Sensors, 2016, 16(11), 1951. (SCI)
[15] Y. Yan, X. Cui, M. Guo, X. Han. Localization of a Continuous CO2 Leak from an Isotropic Flat-Surface Structure Using Acoustic Emission Detection and Near-Field Beamforming Techniques. Measurement Science and Technology. 2016, 27, 115105. (SCI)
[16] Y. Yan, Y. Shen, X. Cui, Y. Hu. Localization of Multiple Leak Sources Using Acoustic Emission Sensors Based on MUSIC Algorithm and Wavelet Packet Analysis. IEEE Sensors Journal, 2018, 18(23): 9812-9820. (SCI)
[17] X. Ge, H. Ji, X. Cui. Movement Behavior and Partial Discharge of the Single Metallic Particle in GIS at Operated Voltage. IEEE Transactions on Plasma Science, 2019, 47(9):4319-4328. (SCI)
[18] Y. Ma, Y. Gao, X. Cui, M. J. Brennan, J. Yang, Adaptive phase transform method for pipeline leakage detection. Sensors, 2019, 19(2), 310. (SCI)
[19] X. Han, F. Chen, X. Cui, Y. Li, X. Li. A Power Smoothing Control Strategy and Optimized Allocation of Battery Capacity Based on Hybrid Storage Energy Technology. Energies, 2012, 5(5): 1593-1612. (SCI)
[20] H. Ji, C. Li, Z. Pang, G. Ma, X. Cui, et al. Moving Behaviors and Harmfulness Analysis of Multiple Linear Metal Particles in GIS. IEEE Transactions on Dielectrics and Electrical Insulation, 2016, 23(6): 3355-3363. (SCI)
科研成果
[1] 一种基于声波主动激励的地下非金属管线探测系统及方法. 发明专利:ZL 2022 1 1415031.4
[2] 基于碰撞声特征的生物质颗粒粒径识别系统及方法. 发明专利:ZL 2022 1 1370029.X
[3] 基于声阵列椭圆轨迹的地下非金属管线探测系统及方法. 发明专利:CN 202310911913.8
[4] 一种基于不匹配传感器混用的管道泄漏检测系统及方法. 发明专利:CN 202311072969.5
[5] 一种基于自适应滤波器的管道泄漏定位装置. 发明专利:ZL 2019 1 0699473.8.
[6] 一种基于声波反射的埋地管线探测装置及方法. 发明专利:ZL 2018 1 0083685.9.
[7] 一种基于极性零点检测的时延估计方法及系统. 发明专利:ZL 2019 1 0689877.9.
[8] 一种基于互相关的管道泄漏定位方法. 发明专利:ZL 2018 1 0083681.0.
[9] 一种基于低频流体波特征识别的充液管道泄漏检测方法. 发明专利:CN 202211122824.7
[10]一种基于共振腔调制的埋地管道微小泄漏检测方法及系统. 发明专利:CN 202410350162.1.
[11] 一种浅层埋地非金属物体探测系统. 实用新型:ZL 2019 2 1220801.3.