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何向阁, 文鹏飞, 杨辉, 等. 基于分布式光纤传感技术实现的小道距海上拖缆地震数据采集系统. 石油物探, 2022, 61(1): 70-77.
He Xiangge, Wu Xuemin, Wang Lei, Liang Qianyong, Gu Lijuan, Liu Fei, Lu Hailong, Zhang Yi, and Zhang Min, “Distributed optical fiber acoustic sensor for in situ monitoring of marine natural gas hydrate production,” China Geology, 2022, 5(2): 322-329.
He, Xiangge, Shangran Xie, Lijuan Gu, Fei Liu, Min Zhang, and Hailong Lu. "High-resolution quasi-distributed temperature and pressure sensing system for deep-sea reservoir monitoring." Measurement 199 (2022): 111568.
Liu Fei, Yi Duo, Chen Yi, Xu Ping, Zhang Min, Zhu Xuewen, He Xiangge, Zhou Xian, and Long Keping, "Common-mode noise self-suppressed 3-component fiber optic accelerometer based on low-reflectivity Bragg gratings," Optics Letters, 46(7), 1596-1599 (2021).
Liu Fei, Xie Shangran, Zhang Min, Tang Chunhua, Xie Bin, He Xiangge, Gu Lijuan, Lu Hailong, Zhou Xian, and Long Keping, "Downhole Microseismic Monitoring Using FOSS and Its Field Test Comparison With Moving-Coil Geophone," IEEE Transactions on Geoscience and Remote Sensing, 60, 1-14 (2021).
He X, Zhang M, Gu L, et al. Performance Improvement of Dual-Pulse Heterodyne Distributed Acoustic Sensor for Sound Detection. Sensors, 2020, 20(4)
He X, Xu X, Zhang M, et al. On the phase fading effect in the dual-pulse heterodyne demodulated distributed acoustic sensing system. Optics Express, 2020, 28(22): 33433
Liu F, Xie S, Zhang M, et al. Downhole Microseismic Monitoring Using Time-Division Multiplexed Fiber-Optic Accelerometer Array. IEEE Access, 2020, 8: 120104~120113
Liu Fei, Xie Shangran,Gu Lijuan, He Xiangge, Yi Duo, Chen Zhangyuan, Zhang Min and Tao Qingchang,Common-mode noise suppression technique in interferometric fiber-optic sensors,Journal of Lightwave Technology,37,21:5619-5627,SCI收录,2019.11
Yi Duo, Liu Fei , Zhang Min ,Tao Qingchang,High-accuracy transient response fiber optic seismic accelerometer using a shock-absorbing ring as a mechanical antiresonator,Optics Letters,44,2:183-186,44,2:183-186,2019.01
Cao, S., Xie, S., & Zhang, M.* (2016). Polarization beat length estimation based on the statistical properties of Brillouin gain in SMF. IEEE Photonics Technology Letters, 28(18), 1960-1963. (JCR-3, IF: 2.375)
He, X., Xie, S., Cao, S., Liu, F., Zheng, X., Zhang, M.*, & Chen, G. (2016). Influence of stimulated Brillouin scattering on positioning accuracy of long-range dual Mach–Zehnder interferometric vibration sensors. Optical Engineering, 55(11), 116111.( JCR-4, IF: 1.082)
Liu, F., Xie, S., Qiu, X., Wang, X., Cao, S., Qin, M., & Zhang, M. * (2016). Efficient common-mode noise suppression for fiber-optic interferometric sensor using heterodyne demodulation. Journal of Lightwave Technology, 34(23), 5453-5461. ( JCR-2, IF: 3.671)
Yi, D., & Zhang, M.* (2017). Heat flux investigations during flame thermal spray process using the lumped capacitance method. Applied Thermal Engineering, 123, 554-561. ( JCR-2, IF: 3.444)
Cao, S., & Zhang, M. * (2017). Polarized and birefringence-dependent stimulated Brillouin scattering in single mode fiber. Optik-International Journal for Light and Electron Optics, 131, 374-382. ( JCR-4, IF: 0.835)
Yi, D., Zhang, M., Gu, L., Yang, J., & Yu, W. (2017). Finite element analysis of fiber optic embedded in thermal spray coating. Journal of Intelligent Material Systems and Structures, 1045389X17721057. (JCR-3, IF:2.255 )
Lin, Y., Liu, F., He, X., Jin, W., Zhang, M., Yang, F., & Gu, L. (2017). Distributed gas sensing with optical fibre photothermal interferometry. Optics express, 25(25), 31568-31585. (JCR-2, IF:3.307)
刘飞, 颜晗, 华波, 郑小平, & 张敏*. (2017). 载波相位偏差对光纤检波器解调的影响. 光学学报, 37(9), 0906001.
He, X., Xie, S., Liu, F., Cao, S., Gu, L., Zheng, X., & Zhang, M. *(2017). Multi-event waveform-retrieved distributed optical fiber acoustic sensor using dual-pulse heterodyne phase-sensitive OTDR. Optics letters, 42(3), 442-445. (JCR-2, IF:3.416)
Cao, S., Xie, S., Liu, F., Zheng, X., & Zhang, M.* (2017). Numerical and experimental analysis of polarization dependent gain vector in Brillouin amplification system. Optics Communications, 389, 23-28. (JCR-2, IF:1.588)