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冯其波

职称:教授

学历:研究生

学位:博士

电话:

邮箱:qbfeng@bjtu.edu.cn

教育背景

1979.09~1983.07,合肥工业大学精密仪器系,获得工学学士学位;

1983.07~1986.04,合肥工业大学精密仪器系,获得工学硕士学位;

1990.02~1993.03,清华大学精密仪器及机械学系,获得光学仪器工学博士学位;

1998.10~1999.10,在University of North Carolina at Charlotte留学访问1年。

工作经历

教学科研:

      1986.04~1990.02 合肥工业大学精密仪器系助教;

      1993.03~1995.10 北方交通大学 讲师;

      1995.10~2000.10 北方交通大学 副教授;

      2000.10~现在 北京交通大学教授、博士生导师、3级教授、2级教授。

管理经历

2001.06~2005.05 理学院 副院长;

2005.5~2017.12  理学院 院长;

2008年~现在 光学工程责任教授。

研究方向
  • 光电检测与光电传感
  • 光电信息工程
招生专业
  • 光学工程硕士
  • 光电信息工程硕士
科研项目

主持的纵向项目(50万以上)

  1. 科技部雄安科技创新专项任务,激光高精度多参数快速综合测量仪研发与应用(2022XAGG0200),20220/-2024/07,300万. 

  2. 红果园省部级"企事业"(新),微型原位高精度六自由度相对位姿测量系统,202108-202202,582万.

  3. 红果园省部级"企事业"(新),高精度角度测量装置生产、装调、检测,202107-202112,96万.
  4. 国家自然科学基金重点项目:高速重载极端条件下轮对状态动态监测基础问题与关键技术研究,2020.1-2024.12.300万
  5. 国家重大科研仪器研制项目:面向五轴数控机床的激光高精度多参数快速综合测量仪研制与应用,2016.1-2020.12,845万.
  6. 国家自然科学基金“面上”:轮对几何参数在线测量方法与动态误差补偿的研究,2013.1-2016.12,80万.
  7. 国家自然科学基金“重点”:激光六自由度误差同时测量仪的研制,2011.1-2013.12,180万.
  8. 863项目:重载铁路桥梁和路基检测与强化技术-重载铁路路基静动力性能检测、连续检测、实时监测与状态评估技术研究,2009-2011,100万.
  9. 863项目:客运专线路基沉降全方位实时监测技术的研究,2007.12-2009.12,100万.

主持的主要横向项目 (50万元以上)

  1. 列车轮对智能检测及全寿命周期管理系统研发与产业化获东莞市第三批创新科研团队支持,总经费4000万,其中政府支持1000万.
  2. 北京交通大学:轨道交通检测仪器与设备研制,2016-2020,180万.
  3. 北京交通大学:声屏障检测技术,2014.7-2015.12,60万.
  4. 北京交通大学:机车轮对几何参数动态在线测量系统 ,2013.10--2014.6,100万.
  5. 北京交大创新科技中心:轨检车用专用激光线光源3,2011.12--2012.3.64万.
  6. 北京交大科技发展中心:非接触式静态轨道几何状态检测小车,2005.10-2006.02,96万.
教学工作


  1. 开设《光电检测技术》等本科生主干课程和《光学测量》博士生学位课,曾被学生评为最受欢迎的教师;
  2. 《大学物理实验》国家级精品资源共享课负责人;
  3. 共招收博士研究生37名,其中25名毕业获得博士学位,1名博士毕业获得国家杰出青年基金;共招收76名硕士研究生,其中57毕业获得硕士学位
  4. 2013年被评为北京市优秀教师。


论文/期刊

SCI检索期刊论文


1.        Guo Xiaoxuan; Ji Zhenyan; Feng Qibo; Wang Huihui; Yang Yanyan; Li Zhao. URS: A Light-Weight Segmentation Model for Train Wheelset Monitoring, IEEE Transactions on Intelligent Transportation Systems, 2023,24(7):7707~7716.

2.        Zheng Fajia; Long Fei; Zhao Yuqiong; Yu Chunyu; Jia Peizhi; Zhang Bin;Yuan Ding; Feng Qibo*.High-Precision Small-Angle Measurement of Laser-Fiber Autocollimation Using Common-Path Polarized Light Difference. IEEE Sensors Journal, 2023,23(9):9237~9245

3.        Zheng Fajia; Liu Zhijia; Long Fei; Fang Hongjun; Jia Peizhi; Xu Zhiming; Zhao Yuqiong; Li Jiakun; Zhang Bin; Feng Qibo*. High-precision method for simultaneously measuring the six-degree-of-freedom relative position and pose deformation of satellites. Optics Express,2023, 31(8):13195~13210

4.        Fu Wenjie; He Qixin*; Feng Qibo; Li Jiakun; Zheng Fajia; Zhang Bin. Recent Advances in Wayside Railway Wheel Flat Detection Techniques: A Review. Sensors,2023, 23(IS 8):3916/DI 10.3390/s23083916

5.        Qian Yibin; Li Jiakun*; Feng Qibo; He Qixin; Long Fei. Error Analysis of Heterodyne Interferometry Based on One Single-Mode Polarization-Maintaining Fiber. Sensors,2023, 23(IS 8)/DI 10.3390/s23084108.

6.        Gao Jiongye; Zhang Bin*; Feng Qibo; Shen Xu; Xue Yong; Liu Jiacheng. Speckle Measurement for Small In-Plane Vibration Using GaAs, Sensors, 2023,23(5):2724.

7.        He Qixin*; Chang Jvqiang; Li Mengxin; Li Jiakun; Feng Qibo. Oxygen detection based on Faraday modulation spectroscopy and wavelength modulation spectroscopy: A comparison. Microwave and Optical Technology Letters,2023, 65(IS 5):1353~1358.

8.        Jia Peizhi; Li Peng; Zheng Fajia; Feng Qibo*; Zhang Bin. Simultaneous measurement of 5DOF spindle error motions in CNC machine tools, Applied Optics, 2022,61(19):5704-5713/10.1364/AO.456727.

9.        Ji Zhenyan*; Song Xiaojun; Feng Qibo; Wang Haishuai; Chen Chi-Hua; Chang Chin-Chen. RSG-Net: A Recurrent Similarity Network With Ghost Convolution for Wheelset Laser Stripe Image Inpainting, IEEE Transactions on Intelligent Transportation Systems,2022/10.1109/TITS.2022.3176222.

10.    Chang Jvqiang; He Qixin; Li Jiakun; Feng Qibo. Oxygen detection system based on TDLAS-WMS and a compact multipass gas cell,    Microwave and Optical Technology Letters .2022/10.1002/mop.33203.

11.    Peizhi Jia; Bin Zhang; Fajia Zheng and Feng Qibo*. Comprehensive measurement model of geometric errors for three linear axes of computer numerical control machine tools. Meas. Sci. Technol. 33(2022)015202.

12.    Ran Yunfeng; He Qixin; Feng Qibo*; Cui Jianying. On-Site Calibration Method for Line-Structured Light Sensor-Based Railway Wheel Size Measurement System. Sensors 21(2021)6717.

13.    He Qixin; Li Jiakun; Feng Qibo*. Development of a Mid-Infrared Cavity Enhanced Formaldehyde Detection System. Spectroscopy and Spectral Analysis 41(2021)2077.

14.    Gao ZH; Zhang WX; Yan BX.; Kong XX.; Zhao YS.; Wu Z.; Guo X L.; Feng QB*. A tunable single-frequency green laser based on a wedged Nd:YVO4 crystal and a KTP crystal. Laser Phys.31(2021)065002.

15.    Ma Dong; Li Jiakun*; Feng Qibo; He Qixin; Ding Yaowen; Cui Jianying. Simultaneous measurement method and error analysis of six degrees of freedom motion errors of a rotary axis based on polyhedral prism. Appl. Sci. 11(2021)3960.

16.    Ran Yunfeng; He Qixin*; Feng Qibo; Cui Jianying. High-accuracy on-site measurement of wheel tread geometric parameters by line-structured light vision sensor. IEEE Access 9(2021)52590.

17.    Gao Zhihong; Zhang Wenxi*; Yan Boxia; Kong Xinxin; Zhao Yashuai; Wu Zhou; Guo Xiaoli; Feng Qibo. A tunable single-longitudinal-mode wedge Nd:YVO4 laser with a YVO4 wave-plate. Appl. Phys. B 126(2020)172.

18.    Gao Run; He Qixin*; Feng Qibo; Cui Jianying. In-Service Detection and Quantification of Railway Wheel Flat by the Reflective Optical Position. Sensors 17(2020)496.

19.    Zheng Fajia; Feng Qibo*; Zhang Bin; Li Jiakun; Zhao Yuqiong. A high-precision laser method for directly and quickly measuring 21 geometric motion errors of three linear axes of computer numerical control machine tools. Int J Adv Manuf Technol 109(2020)1285.

20.    Fajia Zheng; Feng Qibo*; Bin Zhang; Jiakun Li and Yuqiong Zhao. Effect of detector installation error on the measurement accuracy of multi-degree -of -freedom geometric errors of a linear axis. Meas. Sci. Technol. 31(2020)094018.

21.    Peizhi Jia; Bin Zhang*; Feng Qibo and Fajia Zheng. Simultaneous Measurement of 6DOF Motion Errors of Linear Guides of CNC Machine Tools Using Different Modes. Sensors 20(2020)3439.

22.    He Qixin; Li Jiakun; Feng Qibo*. Ppb-level formaldehyde detection system based on a 3.6 mu m interband cascade laser and mode-locked cavity enhanced absorption spectroscopy with self-calibration of the locking frequency. Infrared Phys. & Technol. 105(2020)103205.

23.    Han Qiang; Wang Shengchun; Fang Yue; Wang Le; Du Xinyu; Li Hailang; He QiXin; Feng Qibo*. A Rail Fastener Tightness Detection Approach Using Multi-source Visual Sensor. Sensors. 20(2020)1367.

24.    Zheng Fajia; Zhang Bin; Gao Run; Feng Qibo*.A High-Precision Method for Dynamically Measuring Train Wheel Diameter Using Three Laser Displacement Transducers. Sensors 19(2019)4148.

25.    Run Gao, Qixin He and Feng Qibo*.Railway Wheel Flat Detection System Based on a Parallelogram Mechanism. Sensors 19(2019)3614.

26.    Zheng Fajia; Feng Qibo*; Zhang Bin; Li Jiakun. A method for simultaneously measuring 6DOF geometric motion errors of linear and rotary axes using lasers. Sensors 19(2019)1764.

27.    Jiakun Li; Feng Qibo*; Chuanchen Bao; Bin Zhang. Method for simultaneously and directly measuring all six-DOF motion errors of a rotary axis. Chin. Opt. Lett. 17(2019)011203.

28.    He Qixin; Feng Qibo; Li Jiakun. Long-Term Stable Online Acetylene Detection by a CEAS System with Suppression of Cavity Length Drift. Sensors 19(2019)508

29.    Bao Chuanchen; Feng Qibo* Li Jiakun. Simultaneous Measurement Method and Error Analysis of the Six Degrees-of-Freedom Motion Errors of a Rotary Axis. Appl. Sci. 11(2018)2232.

30.    Zhihong Gao; Feng Qibo*; Wenxi Zhang; Xinxin Kong; Boxia Yan; Yan Qi; Zhou Wu; Yang Li. Single longitudinal mode operation in diode-end-pumped wedge Nd:YVO4 laser. Opt. Commun. 424(2018)131.

31.    Chuanchen Bao; Jiakun Li*;Feng Qibo and Bin Zhang. Error-compensation model for simultaneous measurement of five degrees of freedom motion errors of a rotary axis. Meas. Sci. Technol. 29(2018)075004.

32.    Li Jiakun; Feng Qibo*; Bao Chuanchen; Zhao Yuqiong. Method for simultaneous measurement of five DOF motion errors of a rotary axis using a single-mode fiber-coupled laser. Opt. Express 26(2018)2535.

33.    Guang Chen;Feng Qibo*; Keqin Ding; and Zhan Gao. Subpixel displacement measurement method based on the combination of particle swarm optimization and gradient algorithm. Opt. Eng. 56(2017)104101.

34.    Yuqiong Zhao; Bin Zhang*; and Feng Qibo. Measurement system and model for simultaneously measuring 6DOF geometric errors. Opt. Express 25(2017)20993.

35.    Guang Chen*;Feng Qibo;and Keqin Ding. Methods and Systems for High-temperature Strain Measurement of the Main Steam Pipe of a Boiler of a Power Plant While in Service. J. Opt. Soc. Korea 20(2016)770.

36.    Bin Zhang*; Feng Qibo; and Yunfeng Liang. Interferometer with bismuth silicon oxide crystal for vibration measurement. Opt. Eng. 55(2016)091406.

37.    Yuqiong Zhao; Feng Qibo*; Bin Zhang; and Cunxing Cui. Influence of beam radii on a common-path compensation method for laser beam drifts in laser collimation systems. Meas. Sci. Technol. 27(2016)084013.

38.    Xiaojing Gao; Bin Zhang*; Feng Qibo; Xin Xie; and Lianxiang Yang. Nano-vibration measurements using the photoelectromotive force effect in the GaAs crystal. Instrum. Exp. Technol. 59(2016)470.

39.    Cunxing Cui; Feng Qibo*; Bin Zhang; and Yuqiong Zhao. System for simultaneously measuring 6DOF geometric motion errors using a polarization maintaining fiber-coupled dual-frequency laser. Opt. Express 24(2016)6735.

40.    Jing Wang; Feng Qibo *. Residual stress determination of rail tread using a laser ultrasonic technique. Laser Phys. 25(2015)056104.

41.    Cunxing Cui; Feng Qibo*; and Bin Zhang. Compensation for straightness measurement systematic errors in six degree-of-freedom motion error simultaneous measurement system. App. Opt. 54(2015)3122.

42.    Jing Wang*; Feng Qibo. Converging ultrasonic shear-vertical waves generated by a double-line laser and its application for surface defect detection. Jap. J. App. Phys. 54(2015)046602.

43.    Yong Lv*; Feng Qibo; Lishuang Liu; Qingrui Yi; and Yueqiang Li. Application of optical switch in precision measurement system based on multi-collimated beams. Measurement 61(2015)216.

44.    Shuai Gao; Bin Zhang*; Feng Qibo; Cunxing Cui; Shiqian Chen; and Yuqiong Zhao. Errors crosstalk analysis and compensation in the simultaneous measuring system for five-degree-of-freedom geometric error. App. Opt. 54(2015)458.

45.    Yusheng Zhai*; Zhifeng Zhang; Yuling Su; Xinjie Wang; and Feng Qibo. A high-precision roll angle measurement method. Optik 126(2015)4837.

46.    Tong Zhang; Feng Qibo*; Cunxing Cui; and Bin Zhang. Research on error compensation method for dual-beam measurement of roll angle based on rhombic prism. Chin. Opt. Lett.  12(2014)071201.

47.    Shengjia Wang; Zhan Gao*; Guangyu Li; Ziang Feng; and Feng Qibo. Continual mechanical vibration trajectory tracking based on electro-optical heterodyne interferometry. Opt. Express 22(2014)7799.

48.    Yan Gao; Feng Qibo*; and Jianying Cui. A simple method for dynamically measuring the diameters of train wheels using a one-dimensional laser displacement transducer. Opt. Lasers Eng. 53(2014)158.

49.    Feng Qibo *; Bin Zhang; Cunxing Cui; Cuifang Kuang; Yusheng Zhai; and Fengling You. Development of a simple system for simultaneously measuring 6DOF geometric motion errors of a linear guide. Opt. Express 21(2013)25805.

50.    Jing Yang; Feng Qibo*. A new method for measuring subgrade settlement in high-speed railway by using a linear CCD. Measurement 46(2013)1751.

51.    Sijin Wu; Lianqing Zhu; Feng Qibo; and Lianxiang Yang*. Digital shearography with in situ phase shift calibration. Opt. Lasers in Eng. 50(2012)1260.

52.    Yusheng Zhai; Feng Qibo* and Bin Zhang. A simple roll measurement method based on a rectangular-prism. Opt. Laser Technol. 44(2012)839.

53.    Zhan Gao*; Yan Deng; Yiting Duan; Zhifeng Zhang; Cheng Wei; Shiqian Chen; Jianying Cui; and Feng Qibo. Continual in-plane displacement measurement with temporal wavelet transform speckle pattern interferometry. Rev. Sci. Instrum. 83(2012)015107.

54.    Shengwei Ren; Shiping Gu; Guiyang Xu; Zhan Gao; and Feng Qibo*. A new track inspection car based on a laser camera system. Chin. Opt. Lett. 9(2011)031202.

55.    Fengling You; Bin Zhang*; and Feng Qibo. A novel laser straightness measurement method with beam bend compensation. Optik 122(2011)1530.

56.    Meng Zheng*; Feng Qibo; Zhan Gao; Shuangyun Shao; Keqin Ding. Experiments and analyses of a new type optical system for computed radiography. Chin. Opt. Lett. 8(2010)800.

57.    Zhan Gao*; Feng Qibo; Sijin Wu; Fei Cheng; Jianying Cui; Shiqian Chen; Shiqing Jia; and Jianjun Liu. Track irregularity inspection trolley based on fiber-optic gyro. J. Micro-Nanolithography Mems and Moems, 9(2010) 013045.

58.    Benyong Chen*; Enzheng Zhang; Liping Yan; Chaorong Li; Wuhua Tang; and Feng Qibo. A laser interferometer for measuring straightness and its position based on heterodyne interferometry. Rev. Sci. Instrum. 80(2009)115113.

59.    Jinyun Ding; Feng Qibo*; Lianqing Zhang; and Shulian Zhang. Laser frequency splitting method for high-resolution determination of relative stress-optic coefficient and internal stresses in Nd:YAG crystals. App. Opt. 47(2008)5631.

60.    Feng Qibo*; Bin Zhang and Cuifang Kuang. Four degree-of-freedom geometric error measurement system with common-path compensation for laser beam drift. Int. J. Precis. Eng. Manuf. 9(2008)26.

61.    Zhifeng Zhang*; Feng Qibo; Zhan Gao; Cuifang Kuang; Cheng Fei; Zhang Li; and Jinyun Ding. A new laser displacement sensor based on triangulation for gauge real-time measurement. Opt. Laser Technol. 40(2008)252.

62.    Cuifang Kuang*; En Hong; Feng Qibo; Bin Zhang; and Zhifeng Zhang. A novel method to enhance the sensitivity for two-degrees-of-freedom straightness measurement. Meas. Sci. Technol. 18(2007)3795.

63.    Cuifang Kuang*; En Hong; and Feng Qibo. High-accuracy method for measuring two-dimensional angles of a linear guideway. Opt. Eng. 46(2007)051016.

64.    Cuifang Kuang*; Feng Qibo; Bin Zhang; Bin Liu; Shiqian Chen; and Zhifeng Zhang. A four-degree-of-freedom laser measurement system (FDMS) using a single-mode fiber-coupled laser module. Sens. Actuators. A 125(2005)100.

65.    Feng Qibo*; Bin Zhang; and Cuifang Kuang. A straightness measurement system using a single-mode fiber-coupled laser module. Opt. Laser Technol. 36(2004)279.


专著/译著

1.冯其波主编《光学测量原理、技术与应用》,清华大学出版社,2023.8,ISBN 978-302-63068-5.

2.冯其波,谢芳,张斌,高瞻,邵双运 编著《光学测量技术与应用》,清华大学出版社,2008.5,ISBN 978-7-302-17136-2. 

3.焦明星,冯其波,王鸣,刘君 编著.《激光传感与测量》,科学出版社,普通高等学校“十二五"规划教材,2014.6,北京. ISBN 978-7-03-040664-4. 

4.参编英文专著《Laser Scanning, Theory and Applications》:Chapter 28.P543~566,“A New Laser Scanning System for Computed Radiography”.ISBN:978-953-307-205-0. INTECH,2011.04

专利

1.Feng Qibo, Zhang Bin, Cui Cunxing. Laser measurement system and method for measuring 21 GMEs.        US 9,982,997 B2, 2018-5-29.

2.Feng Qibo, Zhang Bin, Gao Zhan, Cui Cunxing. 6DOF error laser simultaneous measurement system with a single polarization maintaining fiber coupling and transmitting the dual-frequency laser. US 9,857,161 B2, 2018-01-02.

3.Feng Qibo, Zhang Bin, Cui Cunxing. Laser measurement system capable of detecting 21 geometric errors.     EP 3,249 350 B1,2019-11-27

4.Feng Qibo, Zhang Bin, Cui; Cunxing. System for simultaneously measuring six-degree-freedom errors by way of dual-frequency lasers being coupled into a single optical fiber. EP 3,190,381 B1,2019-11-06

5.Feng Qibo, Li Jiakun, Zheng Fajia, Yang Jing. Laser measurement system and method for measuring six-degree-freedom geometric error of rotating shaft. US 10,837,766 B2. 20-11-17

6. Feng Qibo, Dong Hui, Zheng Fajia, Shao Shuangyun, Tan Zhizhong, Zhao Xiaohua. Structured light based wheel multiple parameter online measurement system and measurement method thereof. US 10,895,451 B2, 2021-01-10.

7.冯其波,郑发家,杨婧,冉赟丰.轮轨接触状态与车轮踏面故障的激光检测系统与方法,                  ZL 201910912410.6,2020-10-23

8.冯其波,杨婧.便携式车轮直径测量装置与测量方法. ZL 201710291743.2, 2019-05-21.

9.冯其波,杨婧.用于测量转轴六自由度几何误差的激光测量系统及方法.ZL 201611131183.6,2019-03-22.

10.冯其波,杨婧.利用光学方法的声屏障状态测量装置、系统和方法, ZL 201510142850.X,2017-7-14.

11.冯其波,张斌,崔存星.一种可检测21项几何误差的激光测量系统与方法. ZL 201580001345.1,2018-3-9.

12.冯其波,张斌,高瞻,崔存星.单根光纤耦合双频激光六自由度误差同时测量系统. ZL 201480077557.3,2019-8-9.

13.冯其波,高岩,邵双运,崔建英.一种非接触式车轮直径动态测量装置及其测量方法;                   ZL 201410005647.3;2014.01.064.

软件著作权
获奖与荣誉

1.轮对几何参数与故障动态检测关键技术及应用,高等学校科学研究优秀成果奖(科学技术)科技技术进步二等奖;中华人民共和国教育部;排名1/12;2023年。
2.面向数控机床的激光多自由度误差同时测量关键技术及应用,中国仪器仪表学会技术发明一等奖;排名1/6;2022年。

3.轮对几何参数测量关键技术与系统;中国计量测试学会科技进步一等奖;排名第1;2020年。

4.重载铁路桥梁和路基检测与强化技术,高等学校科学研究优秀成果奖(科学技术)科技技术进步一等奖;中华人民共和国教育部;排名2/282012年。

5.工业射线数字成像管道缺陷检测技术研究与设备研制;国家质量监督检验检疫总局科技兴检奖二等奖;排名第3/9;2010年。                                                 

社会兼职

1.第九届中国光学学会理事;

2.第一、二届中国光学工程学会理事;

3.第一届、第二届中国仪器仪表学会设备结构健康监测与预警分会 副理事长;

4.中国仪器仪表学会光机电技术与系统集成分会副理事长;

5.中国计量测试学会计量仪器专业委员会副主任委员;

6.第六、七届中国计量测试学会理事会 常务理事

7.第一届全国设备结构健康监测标准化工作组 副主任委员;

8.第一、二、三届全国光电测量标准化委员会 委员。