[1] W. Liang, L. Lu, and L. Zhang, “Coupling relations and early-warning for ‘equipment chain’ in long-distance pipeline,” Mechanical Systems and Signal Processing, 2013, 41(1): 335-347.
[2] J. Kang and Z. H Zou, “Time prediction model for pipeline leakage based on grey relational analysis,” Physics Procedia, 2010, 25(2): 2019-2024.
[3] T. Zhang, Y. Tan, H. Yang, J. Zhao, and X. Zhang, “Locating gas pipeline leakage based on stimulus-response method,” Energy Procedia, 2014, 61: 207-210.
[4] Q. Fu, H. J. Wang, and F. Qiu, “Pipeline leak detection based on fiber optic early-warning system,” Procedia Engineering, 2010, 7: 88-93.
[5] Z. Qu, S. Jin, and Y. Zhou, “Study on the distributed optical fiber pipeline leakage pre-warning system and the method of signal analysis,” in Proceedings of the 6th International Pipeline Conference, Calgary, Canada, pp. 677-681, 2006.
[6] W. Liang, L. Zhang, Q. Xu, and C. Yan, “Gas pipeline leakage detection based on acoustic technology,” Engineering Failure Analysis, 2013, 31(6): 1-7.
[7] Z. Qu, H. Feng, Z. Zeng, J. Zhuge, and S. Jin, “A SVM-based pipeline leakage detection and pre-warning system,” Measurement, 2010, 43(4): 513-519.
[8] Q. Lv, L. Li, H. Wang, Q. Li, and X. Zhong, “Influences of laser on fiber-optical distributed disturbance sensor based on Ф-OTDR,” Infrared and Laser Engineering, 2014,12(43): 3919-3923.
[9] H. F. Martins, S. Martin-Lopez, P. Corredera, and M. L. Filograno, “Coherent noise reduction in high visibility phase-Sensitive optical time domain reflectometer for distributed sensing of ultrasonic waves,” Journal of Lightwave Technology, 2013, 31(23): 3631-3637.
[10] Q. Li, C. Zhang, L. Li, and X. Zhong, “Localization mechanisms and location methods of the disturbance sensor based on phase-sensitive OTDR,” Optik-Interntional Journal for Light and Electron Optics, 2014, 125(9): 2099-2103.
[11] Q. Lin, C. Zhang, and C. Li, “Fiber-optic distributed sensor based on phase- sensitive OTDR and wavelet packet transform for multiple disturbances location,” Optik-Interntional Journal for Light and Electron Optics, 2014, 125(24): 7235-7238.
[12] A. R. Bahrampour and F. Maaoumi, “Resolution enhancement in long pulse OTDR for application in structural health monitoring,” Optical Fiber Technology, 2010, 16(24): 240-249.
[13] L. Lu, Y. Song, X. Zhang, and F. Zhu, “Frequency division multiplexing OTDR with fast signal processing,” Optics and Laser Technology, 2012, 44(7): 2206-2209.
[14] Z. Qin, “Distributed optical fiber vibration sensor based on Rayleigh backscattering,” Ph.D. dissertation, University of Ottawa, Ottawa, 2013.
[15] H. Rohling, “Radar CFAR thresholding in clutter and multiple target situations,” IEEE Transactions on Aerospace and Electronic Systems, 1983, AES-19(4): 608-621.
[16] M. E. Smith and P. K. Varshney, “Intelligent CFAR processor based on data variability,” IEEE Transactions on Aerospace and Electronic Systems, 2000, 36(3): 837-847.
[17] S. Ward, M. Bélanger, D. Donovan, A. Horsman, and N. Carrier, “Automatic censored CFAR detection for nonhomogeneous environments,” IEEE Transactions on Aerospace and Electronic Systems, 1992, 28(1): 286-304.
[18] R. Zhang, W. Sheng, and X Ma, “Improved switching CFAR detector for non-homogeneous environments,” Signal Processing, 2013, 93(1): 35-48.
[19] G. V. Weinberg, “Management of interference in Pareto CFAR processes using adaptive test cell analysis,” Signal Processing, 2014, 104: 264-273.
[20] B. Shi, C. Hao, C. Hou, X. Ma, and C Peng, “Parametric Rao test for multichannel adaptive detection of range-spread target in partially homogeneous environments,” Signal Processing 2015, 108: 421-429.
