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张敏
2023-05-06 08:53
  • 张敏
  • 张敏 - 副研究员-北京大学-海洋研究院-个人资料

近期热点

资料介绍

个人简历


教育背景
博士 (2003) 香港理工大学电机工程系,专业方向:光纤传感
硕士 (1999) 清华大学精密仪器与机械学系,专业方向:光学工程
本科 (1996) 清华大学精密仪器与机械学系,专业方向:仪器仪表
工作经历
2003-2006 清华大学电子工程系助理教授
2006-2016 清华大学电子工程系副教授
2016-2018 北京大学海洋研究院助理研究员
2018-现在 北京大学海洋研究院副研究员
研究课题
1、2003年11月回国参加工作,参加了国家十五海洋863重大项目“时移地震采集关键设备研制”和“钻井中途油气层测试技术”中光纤传感技术的研究,成为研究骨干,负责总体技术方案。该课题于十一五期间得到延续,因此在2006年12月~2010年12月期间,作为子课题负责人,承接并完成了十一五国家高技术研究发展计划(863)“深水高精度地震勘探技术”子课题“光纤检波器地震拖缆研制”任务(2006AA0AA102-03),在国内第一次研制成功基于光源内调制的硬件集成化光纤检波器地震拖缆系统,并进行了实际海洋地震采集实验,取得了大量关键技术成果。包括空气腔芯轴型光纤水听器的设计方法和参数控制方法,基于光源内调制的光纤水听器相位生成载波解调方法与算法,基于光源内调制的光纤水听器参数椭圆估计算法,光纤水听器拖曳缆的结构设计方法和制作方法等等。
2、2007年1月~2009年12月,在光纤多参量传感技术研究方面,参加了靳伟教授主持的国家自然科学基金港澳杰出青年基金项目“基于光子晶体光纤的传感机理与应用研究”,以此为基础,于2008年1月~2010年12月独立承担并完成了国家自然科学基金项目与中国工程物理研究院联合基金(NSAF联合基金)项目“微量气体组分光纤测试技术研究”( 10776016),在基于微型光纤FP腔氢气传感技术研究上取得突破,实现了适用于密闭环境的微量氢气的高灵敏度探测,课题于2011年获得国家自然科学基金与中国工程物理研究院联合基金优秀奖。。
3、2007年1月~2010年9月,负责并完成了十一五国家科技支撑项目课题“海缆敷设与电缆安全运营智能保障系统的研究”任务(2007BAE19B04),研制成功基于双向MZ干涉仪结构的分布式光纤振动传感系统,在舟山电力公司220kV海底电力电缆系统在线监护中得到应用,取得良好的监测效果,该项目成果被宁波诺可电子科技发展有限公司转化成产品,获得2011年宁波市科技进步三等奖和2012年浙江省科技进步三等奖。
4、2007年~2010年,负责并完成了十一五国防预研项目“XX光纤阵列研究”,取得了基于补偿干涉仪和PGC调制解调技术的全光阵列的关键技术突破,在湖上试验中获得了优于零级海况噪声的系统性能,为全光纤系统的后续研制奠定了坚实的基础。在后续研究中进一步提出并研制了基于光频差分调制解调技术的全光纤水听器复合复用方法和系统设计方法,形成了基于硬件解调的差频调制解调算法内核,在高稳定性高性能光纤水听器系统技术研究方面取得了重要的成果。
5、2013年1月至今,负责承担了十二五“863”资源环境技术领域主题项目“超深稠油油藏井筒降粘关键技术“之子课题“稠油热采井光纤高温高压测试仪器及解释软件平台开发”,并以此课题的阶段成果为基础,为中国石油新疆油田分公司的风城油田开发了SAGD蒸汽腔前缘光纤监测仪器和井下光纤微地震监测系统,进行了诺干井次的现场实验,为后续进行多分量海底光纤地震采集缆(OBC)的研制建立了关键的技术基础。

专利
1、申请号: CN201510259956,
申请日: 2015.05.20
公开(公告)号: CN104901765A
公开(公告)日: 2015.09.09
发明名称: 一种基于FPGA的数据解调方法及系统
IPC分类号: H04B10/25; H04J14/08
申请(专利权)人: 清华大学;
发明人: 张敏;刘飞;王笑非;匡武
2、申请号: CN201410375008
申请日: 2014.07.31
公开(公告)号: CN104166014A
公开(公告)日: 2014.11.26
发明名称: 基于加速度传感器获取加速度信号的方法、加速度传感器
IPC分类号: G01P15/03;
申请(专利权)人: 清华大学;
发明人: 张敏; 王笑非; 周宏朴
3、申请号: CN201310224673
申请日: 2013.06.06
公开(公告)号¬: CN103335949A
公开(公告)日: 2013.10.02
发明名称: EFPI光纤传感器
IPC分类号: G01L11/02; G01N21/17;
申请(专利权)人: 清华大学;
发明人: 张敏; 赵子文; 廖延彪; 王为宇; 谢尚然
4、申请号: CN201210229488
申请日: 2012.07.03
公开(公告)号: CN102759396A
公开(公告)日: 2012.10.31
发明名称: 抑制光纤水听器系统光强波动影响的方法
IPC分类号: G01H9/00;
申请(专利权)人: 清华大学;
发明人: 张敏; 王凯; 田长栋; 王利威; 施清平; 张华勇; 戴之光; 肖尧文; 廖延彪
5、申请号: CN201210143601
申请日: 2012.05.09
公开(公告)号: CN102680072A
公开(公告)日: 2012.09.19
发明名称: 用于光纤水听器PGC时分复用系统降噪的系统及方法
IPC分类号: G01H9/00;
申请(专利权)人: 清华大学;
发明人: 张敏; 田长栋; 戴之光; 张华勇; 屠东升; 王凯
6、申请号: CN201210083924
申请日: 2012.03.27
公开(公告)号: CN102590554A
公开(公告)日: 2012.07.18
发明名称: 一种基于弹性形变的光纤加速度传感器
IPC分类号: G01P15/03;
申请(专利权)人: 清华大学;
发明人: 张敏; 杨昌; 周宏朴; 廖延彪
7、申请号: CN201110191719
申请日: 2011.07.08
公开(公告)号¬: CN102359797A
公开(公告)日: 2012.02.22
发明名称: 用于光纤水听器中PGC系统降噪的系统及方法
IPC分类号: G01D21/00; H04B10/158; H04L25/03; H04L27/22;
申请(专利权)人: 清华大学;
发明人: 张敏; 田长栋; 戴之光; 王利威; 廖延彪
8、申请号: CN201010569401
申请日: 2010.11.26
公开(公告)号¬: CN102128815A
公开(公告)日: 2011.07.20
发明名称: 检测时间及位置可控的激光诱导击穿光谱检测装置
IPC分类号: G01N21/63;
申请(专利权)人: 清华大学;
发明人: 马晓红; 赵华凤; 郑泽科; 张敏; 廖延彪
9、申请号: CN200910092602
申请日: 2009.09.14
公开(公告)号: CN101672696A
公开(公告)日: 2010.03.17
发明名称: 一种光偏振检测仪
IPC分类号: G01J4/04;
申请(专利权)人: 清华大学;
发明人: 谢尚然; 黄志能; 王利威; 张敏; 廖延彪;
10、申请号: CN200910087954
申请日: 2009.06.25
公开(公告)号: CN101592757A
公开(公告)日: 2009.12.02
发明名称: 级联长周期光纤光栅装置及其制造方法及湿敏传感系统
IPC分类号: G02B6/02; G01N21/45;
申请(专利权)人: 清华大学;
发明人: 于秀娟; 张敏; 陈明华; 廖延彪; 居剑; 靳伟;
11、申请号: CN200910082777
申请日: 2009.04.29
公开(公告)号¬: CN101539644A
公开(公告)日: 2009.09.23
发明名称: 一种光纤光栅的制作方法及使用该光纤光栅的传感器
IPC分类号: G02B6/02; G01B11/24;
申请(专利权)人: 清华大学;
发明人: 靳伟; 金龙; 陈明华; 张敏; 于秀娟; 廖延彪;
12、申请号: CN200810247340
申请日: 2008.12.30
公开(公告)号: CN101451959A
公开(公告)日: 2009.06.10
发明名称: 一种氢气传感器及钯膜氢敏感系统
IPC分类号: G01N21/00; G01N21/84;
申请(专利权)人: 清华大学;
发明人: 杨振; 张敏; 廖延彪; 田芊; 黎启胜; 张毅; 庄志;
13、申请号: CN200410033614
申请日: 2004.04.13
公开(公告)号: CN1563915A
公开(公告)日: 2005.01.12
发明名称: 无源分光检偏器
IPC分类号: G01J4/00;
申请(专利权)人: 清华大学;
发明人: 张敏; 廖延彪; 赖淑蓉

近期论文


主要论文列表
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7. Shi Q, Tian Q, Wang L, et al. Performance improvement of phase-generated carrier method by eliminating laser-intensity modulation for optical seismometer[J]. Optical Engineering, 2010, 49(2): 024402.
8. Yu X, Childs P, Zhang M, et al. Relative humidity sensor based on cascaded long-period gratings with hydrogel coatings and Fourier demodulation[J]. IEEE Photonics Technology Letters, 2009, 21(24): 1828-1830.
9. Xuan H, Jin W, Zhang M, et al. In-fiber polarimeters based on hollow-core photonic bandgap fibers[J]. Optics express, 2009, 17(15): 13246-13254.
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17. Dong S, Liao Y, Zhang M, et al. Effects of chemical modification on fusion splicing strength and optical parameters of optical fiber[J]. Optical engineering, 2005, 44(1): 015002.
18. Zhang M, Wang D N, Jin W, et al. Wavelength modulation technique for intra-cavity absorption gas sensor[J]. IEEE transactions on instrumentation and measurement, 2004, 53(1): 136-139.
19. Wang X, Qiu X, Hu C, et al. Research on a dual polarization-maintaining FBG accelerometer[C]//2015 International Conference on Optical Instruments and Technology: Optical Sensors and Applications. International Society for Optics and Photonics, 2015, 9620: 96200Q.
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21. GB/T 7714
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147. He X, Xie S, Cao S, et al. Influence of stimulated Brillouin scattering on positioning accuracy of long-range dual Mach–Zehnder interferometric vibration sensors[J]. Optical Engineering, 2016, 55(11): 116111.
148. Cao S, Xie S, Zhang M. Polarization beat length estimation based on the statistical properties of Brillouin gain in SMF[J]. IEEE Photonics Technology Letters, 2016, 28(18): 1960-1963.
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学术兼职
中国光学工程学会光学传感技术专家工作委员会暨中国光纤传感技术及产业创新联盟副主席
中国光学学会光电技术专业委员会委员,集成与纤维光学专业委员会委员
中国仪器仪表学会光机电技术与系统集成分会理事、仪表元器件学会光纤传感器专业委员会委员
中国电子学会敏感技术学会光纤传感器专业分会委员
中国光纤传感学术会议暨产业化论坛执行委员会委员

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