[1] Y Sung, C Moon, S Eom, et al. Coal-particle size effects on NO reduction and burnout characteristics with air-staged combustion in a pulverized coal-fired furnace. Fuel, 182, 558-567(2016).

[2] Q Li, J Jiang, Q Zhang, et al. Influences of coal size, volatile matter content, and additive on primary particulate matter emissions from household stove combustion. Fuel, 182, 780-787(2016).

[3] X S Cai, J F Li, O Y Xin, et al. In-line measurement of pneumatically conveyed particles by a light transmission fluctuation method. Flow Measurement and Instrumentation, 16, 315-320(2005).

[4] Liang Liang, Shoufeng T Tang, Minming T Tong, et al. Study on the detection method of the granularity of pulverized coal based on THz time-domain chaos features. Spectroscopy and Spectral Analysis, 39, 1392-1397(2019).

[5] G Zhang, Y Yan, Y Hu, et al. On-line size measurement of pneumatically conveyed particles through acoustic emission sensing. Powder Technology, 353, 195-201(2019).

[6] J F Gu, M X Su, X S Cai. In-line measurement of pulverized coal concentration and size in pneumatic pipelines using dual-frequency ultrasound. Applied Acoustics, 138, 163-170(2018).

[7] L Gao, Y Yan, R M Carter, et al. On-line particle sizing of pneumatically conveyed biomass particles using piezoelectric sensors. Fuel, 113, 810-816(2013).

[8] X Qian, Y Yan, L Wang, et al. An integrated multi-channel electrostatic sensing and digital imaging system for the on-line measurement of biomass–coal particles in fuel injection pipelines. Fuel, 151, 2-10(2015).

[9] U Ulusoy, C Igathinathane. Particle size distribution modeling of milled coals by dynamic image analysis and mechanical sieving. Fuel Processing Technology, 143, 100-109(2016).

[10] X C Wu, Y C Wu, C C Zhang, et al. Fundamental research on the size and velocity measurements of coal powder by trajectory imaging. Journal of Zhejiang University-Science A, 14, 377-382(2013).

[11] S Qin, X Cai. Online measurement of size distribution of pulverized coal with light fluctuation method. Journal of Chinese Society of Power Engineering, 38, 272-277(2018).

[12] Yingchun Wu, Xuecheng Wu, Kefa Cen. Development of digital holography in particle field measurement. Chinese J Lasers, 41, 0601001(2014).

[13] X Wu, Q Jin, L Zhao, et al. Digital holographic sizer for coal powder size distribution measurement: preliminary simulation and experiment. Measurement Science and Technology, 29, 124001(2018).

[14] X C Wu, X D Lin, L C Yao, et al. Primary fragmentation behavior investigation in pulverized coal combustion with high-speed digital inline holography. Energy & Fuels, 33, 8126-8134(2019).

[15] Y C Wu, X C Wu, L C Yao, et al. 3D boundary line measurement of irregular particle with digital holography. Powder Technology, 295, 96-103(2016).

[16] H Li, N Riefler, T Wriedt, et al. Reference data set for three-dimensional measurements of double droplet combustion of p-xylene. Proceedings of the Combustion Institute, 38, 3151-3158(2020).

[17] O Kemppinen, J C Laning, R D Mersmann, et al. Imaging atmospheric aerosol particles from a UAV with digital holography. Scientific Reports, 10, 16085(2020).

[18] Y C Wu, X C Wu, J Yang, et al. Wavelet-based depth-of-field extension, accurate autofocusing, and particle pairing for digital inline particle holography. Applied Optics, 53, 556-564(2014).