[1] Song A C, Zhao Q, Li J W et al. Real-time plume velocity measurement of solid propellant rocket motors using TDLAS technique[J]. Propellants Explosives Pyrotechnics, 46, 636-653(2021).

[2] Huang X L, Li N, Weng C S et al. In situ measurement on nonuniform velocity distribution in external detonation exhaust flow by analysis of spectrum features using TDLAS[J]. Chinese Physics B, 31, 014703(2022).

[3] Ge J, Wang D Y, Li S P. Study on the influence of incoming flow velocity on thrust stability of underwater solid rocket motor[C], 1482(2022).

[4] Cheong K P, Ma L H, Duan K et al. A numerical study of multiline-multiband tomographic absorption spectroscopy for axisymmetric flames[J]. Proceedings of SPIE, 11780, 117801J(2021).

[5] Si J J, Li G L, Cheng Y B et al. Hierarchical temperature imaging using pseudo-inversed convolutional neural network aided TDLAS tomography[J]. IEEE Transactions on Instrumentation and Measurement, 70, 4506711(2021).

[6] Bendana F A, Sanders I C, Stacy N G et al. Localized characteristic velocity (c) for rocket combustion analysis based on gas temperature and composition via laser absorption spectroscopy[J]. Measurement Science and Technology, 32, 125203(2021).

[7] Deng B T, Sima C T, Xiao Y F et al. Modified laser scanning technique in wavelength modulation spectroscopy for advanced TDLAS gas sensing[J]. Optics and Lasers in Engineering, 151, 106906(2022).

[8] Dai J H, Yu T, Xu L J et al. On the regularization for nonlinear tomographic absorption spectroscopy[J]. Journal of Quantitative Spectroscopy and Radiative Transfer, 206, 233-241(2018).

[9] Ye W L, Liu W H, Xia Z K et al. Study of multi-parameter in TDLAS detection system based on LabVIEW[C], 1170-1175(2021).

[10] Thurmond K, Dunn I, Ahmed K A et al. Measurements of H2O, CO2, CO, and static temperature inside rotating detonation engines[C], 0747(2019).

[11] Zhai Y C, Wang F, Chi Y et al. Optical absorption tomography for temperature and H2O concentration imaging by a compact photoelectric detecting system combined with twice adaptive algebraic algorithm[J]. Optical Engineering, 61, 034103(2022).

[12] Wang X P, Peng D, Li J S et al. Two-dimensional reconstruction of combustion flow field using wavelength-modulated absorption spectra[J]. Chinese Journal of Lasers, 48, 0711002(2021).

[13] Li M X, Xu Z Y, Kan R F et al. Development of laser gas analyzer for eddy correlation method[J]. Chinese Journal of Lasers, 48, 1111001(2021).

[14] Fu B, Zhang C H, Lyu W H et al. Recent progress on laser absorption spectroscopy for determination of gaseous chemical species[J]. Applied Spectroscopy Reviews, 57, 112-152(2022).

[15] Ma L H, Ning H B, Wu J J et al. In situ flame temperature measurements using a mid-infrared two-line H2O laser-absorption thermometry[J]. Combustion Science and Technology, 190, 393-408(2018).

[16] Sun L Q, Zou M L, Wang X. Application of tunable diode laser absorption spectroscopy in breath diagnosis[J]. Chinese Journal of Lasers, 48, 1511001(2021).

[17] Rao W, Xin M Y, Song J L et al. Resolution analysis of tunable diode laser absorption spectroscopy system for velocity measurement of the scramjet combustion flow[J]. Optical Engineering, 58, 114101(2019).

[18] Huang X L, Li N, Weng C S et al. Analysis of nozzle effect on pulsed detonation engine performance based on laser absorption spectroscopy with Doppler frequency shift[J]. Proceedings of SPIE, 10155, 101552W(2016).

[19] Huang A, Cao Z, Wang C R et al. An FPGA-based on-chip neural network for TDLAS tomography in dynamic flames[J]. IEEE Transactions on Instrumentation and Measurement, 70, 4506911(2021).

[20] Jing W Y, Cao Z, Zhang H Y et al. A reconfigurable parallel data acquisition system for tunable diode laser absorption spectroscopy tomography[J]. IEEE Sensors Journal, 17, 8215-8223(2017).

[21] Qu Q W, Cao Z, Xu L J et al. Reconstruction of two-dimensional velocity distribution in scramjet by laser absorption spectroscopy tomography[J]. Applied Optics, 58, 205-212(2019).

[22] Qu Q W, Gao S, Chang L Y et al. Three-dimensional laser absorption spectroscopy velocimetry for high-speed flow diagnosis[J]. Applied Physics B, 125, 129(2019).

[23] Zhai Y C, Wang F. Studies on gas concentration reconstruction methods for simultaneous temperature and H2O concentration tomographic imaging in a flame based on tunable diode laser absorption spectroscopy[J]. Optical Engineering, 60, 024104(2021).

[24] Wang Z Z, Deguchi Y, Kamimoto T et al. Pulverized coal combustion application of laser-based temperature sensing system using computed tomography-Tunable diode laser absorption spectroscopy (CT-TDLAS)[J]. Fuel, 268, 117370(2020).

[25] Grauer S J, Steinberg A M. Linear absorption tomography with velocimetry (LATV) for multiparameter measurements in high-speed flows[J]. Optics Express, 28, 32676-32692(2020).

[26] Wang C W, Li N, Huang X L et al. Two-stage velocity distribution measurement from multiple projections by tunable diode laser absorption spectrum[J]. Acta Physica Sinica, 68, 247801(2019).

[27] Lü X J. Research on the diagnosis of pulse detonation engine flow field based on laser absorption spectroscopy technology[D](2016).

[28] Gordon I E, Rothman L S, Hargreaves R J et al. The HITRAN2020 molecular spectroscopic database[J]. Journal of Quantitative Spectroscopy and Radiative Transfer, 277, 107949(2022).