[1] Zhang S W. Coherent Spectral Analysis based on Brillouin Scattering of Optical Fibers[D](2021).
[2] Dang H. Research on High Resolution Spectral Analysis Method based on Fiber Rayleigh Scattering[D](2020).
[3] Feng K, Cui J, Dang H et al. An Optoelectronic Equivalent Narrowband Filter for High Resolution Optical Spectrum Analysis[J]. Sensors, 17, s17020348(2017).
[4] Huang C Y, Wang W C. Birefringent Prism based Fourier Transform Spectrometer[J]. Optics Letters, 37, 1559-1561(2012).
[5] Akca B I. Design of a Compact and Ultrahigh-resolution Fourier-transform Spectrometer[J]. Optics Express, 25, 1487-1494(2017).
[6] Wang X J, Long Y X, Zheng H Y et al. Optical System Design of Ultra-high Resolution Micro Spectrometer[J]. Photoelectric Engineering, 45, 170734-170742(2018).
[7] Kazakov V I, Moskaletz O D, Paraskun A S. Spectrum Forming and Detection in the System of Monitoring, based on a Diffraction Grating[C], 9078634(2020).
[8] Zhang Z W. Research on Ultra-high Precision Spectrometer based on Stimulated Brillouin Scattering in Optical Fiber[D](2014).
[9] Ji Y. Research on Tunable Band-pass Microwave Photonic Filter based on SBS[D](2017).
[10] Choudhary A, Aryanfar I, Shahnia S et al. Tailoring of the Brillouin Gain for On-chip Widely Tunable and Reconfigurable Broadband Microwave Photonic Filters[J]. Optics Letters, 41, 436-440(2016).
[11] Zhang W, Minasian R A. Switchable and Tunable Microwave Photonic Brillouin-based Filter[J]. IEEE Photonics Journal, 4, 1443-1455(2012).
[12] Hu S L, Li L W, Yi X K et al. Tunable Dual-passband Microwave Photonic Filter based on Stimulated Brillouin Scattering[J]. IEEE Photonics Technology Letters, 29, 330-333(2017).
