[1] Trita A, Vickers G, Mayordomo I et al. Design, integration, and testing of a compact FBG interrogator, based on an AWG spectrometer[J]. Proceedings of SPIE, 9133, 91330D(2014).

[2] Li H Q, Ma X D, Cui B B et al. Chip-scale demonstration of hybrid III-V/silicon photonic integration for an FBG interrogator[J]. Optica, 4, 692-700(2017).

[3] Buck T C, Müller M S, Plattner M et al. Performance analysis of interrogators for fiber Bragg grating sensors based on arrayed waveguide gratings[J]. Proceedings of SPIE, 7389, 738930(2009).

[4] Zhu Y S, Gui L, Zhu Y X. Temperature sensing for wavelength demodulation based on recognition by maximum intensity of radio frequency[J]. Acta Optica Sinica, 39, 0728003(2019).

[5] Zhang W, Su C Q, Zhang M et al. Theory and method for improving optimization objective function in demodulation algorithm of fiber Bragg grating strain distribution[J]. Chinese Journal of Lasers, 46, 0206002(2019).

[6] Xu Y L, Ni Y, Yu T et al. Fiber Bragg grating displacement sensor based on beat frequency demodulation[J]. Laser & Optoelectronics Progress, 56, 170622(2019).

[7] Xu O, Fu X S. Temperature-insensitive method for interrogating fiber grating sensor using dual phase-shifted fiber grating and optoelectronic oscillator[J]. Laser & Optoelectronics Progress, 56, 150601(2019).

[8] Niewczas P, Willshire A J, Dziuda L et al. Performance analysis of the fiber Bragg grating interrogation system based on an arrayed waveguide grating[J]. IEEE Transactions on Instrumentation and Measurement, 53, 1192-1196(2004).

[9] Zhang Z G, Zhang M, Ye P D. MZI-based wavelength interrogation system with tunable-FBG[J]. Optoelectronics Letters, 3, 368-371(2007).

[10] Wu X P, Liu C L, Liu W et al. Monolithic integrated cyclic 64-channel AWG with MZI filters and arrayed vertical reflecting mirrors for WDM-PON application[J]. Applied Optics, 58, 8282-8289(2019).

[11] Mesaritakis C, Argyris A, Grivas E et al. Adaptive interrogation for fast optical sensing based on cascaded micro-ring resonators[J]. IEEE Sensors Journal, 11, 1595-1601(2011).

[12] Thanh L T. Optical biosensors based on multimode interference and microring resonator structures[J]. VNU Journal of Science: Natural Sciences and Technology, 34, 118-127(2018).

[13] Marin Y E, Nannipieri T, Oton C J et al. Current status and future trends of photonic-integrated FBG interrogators[J]. Journal of Lightwave Technology, 36, 946-953(2018).

[14] Marin Y, Nannipieri T, Oton C J et al. Fiber Bragg grating sensor interrogators on chip: challenges and opportunities[J]. Proceedings of SPIE, 1032, 103230D(2017).

[15] Marin Y E, Celik A, Faralli S et al. Integrated dynamic wavelength division multiplexed FBG sensor interrogator on a silicon photonic chip[J]. Journal of Lightwave Technology, 37, 4770-4775(2019).

[16] Moon H M, Kwak S C, Im K et al. Wavelength interrogation system for quasi-distributed fiber Bragg grating temperature sensors based on a 50-GHz array waveguide grating[J]. IEEE Sensors Journal, 19, 2598-2604(2019).

[17] Aswathy C J, Sheela D A C. An interrogation system for spectrally multiplexed fiber Bragg grating sensors[J]. International Journal of Advanced Research in Electrical, 5, 855-860(2016).

[18] Marin Y E, Nannipieri T, Oton C J et al. Integrated FBG sensors interrogation using active phase demodulation on a silicon photonic platform[J]. Journal of Lightwave Technology, 35, 3374-3379(2017).

[19] Su H, Huang X G. A novel fiber Bragg grating interrogating sensor system based on AWG demultiplexing[J]. Optics Communications, 275, 196-200(2007).

[20] Sano Y, Yoshino T. Fast optical wavelength interrogator employing arrayed waveguide grating for distributed fiber Bragg grating sensors[J]. Journal of Lightwave Technology, 21, 132-139(2003).

[21] Yuan P, Wu Y D, Wang Y et al. A 16-channel arrayed waveguide grating based on SOI platform[J]. Semiconductor Optoelectronics, 37, 313-317, 326(2016).