[1] Shuai P, Chen S L, Wu Y F et al. Navigation principles using X-ray pulsars[J]. Journal of Astronautics, 28, 1538-1543(2007).

[2] Brown R H, Twiss R Q. Interferometry of the intensity fluctuations in light-I. Basic theory: the correlation between photons in coherent beams of radiation[J]. Proceedings of the Royal Society of London Series a Mathematical and Physical Sciences, 242, 300-324(1957).

[3] Brown R H, Twiss R Q. A test of a new type of stellar interferometer on Sirius[J]. Nature, 178, 1046-1048(1956).

[4] Glauber R J. The quantum theory of optical coherence[J]. Physical Review, 130, 2529-2539(1963).

[5] Kunimune Y, Yoda Y, Izumi K et al. Two-photon correlations in X-rays from a synchrotron radiation source[J]. Journal of Synchrotron Radiation, 4, 199-203(1997).

[6] Scarcelli G, Valencia A, Shih Y. Experimental study of the momentum correlation of a pseudothermal field in the photon-counting regime[J]. Physical Review A, 70, 051802(2004).

[7] Scarcelli G, Valencia A, Shih Y. Two-photon interference with thermal light[J]. Europhysics Letters (EPL), 68, 618-624(2004).

[8] Zhang D, Zhai Y H, Wu L A et al. Correlated two-photon imaging with true thermal light[J]. Optics Letters, 30, 2354-2356(2005).

[9] Scarcelli G, Berardi V, Shih Y. Can two-photon correlation of chaotic light be considered as correlation of intensity fluctuations?[J]. Physical Review Letters, 96, 063602(2006).

[10] Gatti A, Bondani M, Lugiato L A et al. Comment on “can two-photon correlation of chaotic light be considered as correlation of intensity fluctuations?”[J]. Physical Review Letters, 98, 039301(2007).

[11] Wang L G, Qamar S, Zhu S Y et al. Hanbury Brown-Twiss effect and thermal light ghost imaging: a unified approach[J]. Physical Review A, 79, 033835(2009).

[12] Jeltes T. McNamara J M, Hogervorst W, et al. Comparison of the Hanbury Brown-Twiss effect for bosons and fermions[J]. Nature, 445, 402-405(2007).

[13] Li L, Guan D S, Liu H C et al. Effect of light polarization on Hanbury Brown-Twiss experiment[J]. Acta Sinica Quantum Optica, 15, 201-206(2009).

[14] Liu X F, Chen X H, Yao X R et al. Lensless ghost imaging with sunlight[J]. Optics Letters, 39, 2314-2317(2014).

[15] Magaña-Loaiza O S, Mirhosseini M, Cross R M et al. Hanbury Brown and Twiss interferometry with twisted light[J]. Science Advances, 2, e1501143(2016).

[16] Yu H, Lu R H, Han S S et al. Fourier-transform ghost imaging with hard X rays[J]. Physical Review Letters, 117, 113901(2016).

[17] Zhao X, Yu H, Lu R H et al. Research on pseudo-thermal source of X-ray Fourier-transform ghost imaging[J]. Acta Optica Sinica, 37, 0511001(2017).

[18] Tan Z J, Yu H, Lu R H et al. Study on Fourier-transform ghost imaging with partially coherent X-ray[J]. Acta Optica Sinica, 37, 0411001(2017).

[19] Zhu R G, Yu H, Lu R H et al. Spatial multiplexing reconstruction for Fourier-transform ghost imaging via sparsity constraints[J]. Optics Express, 26, 2181-2190(2018).

[20] Yang S C, Yu H, Lu R H et al. Simulation of Fourier-transform ghost imaging using polychromatic X-ray sources[J]. Acta Optica Sinica, 39, 0511003(2019).

[21] Gorobtsov O Y, Mercurio G, Brenner G et al. Statistical properties of a free-electron laser revealed by Hanbury Brown-Twiss interferometry[J]. Physical Review A, 95, 023843(2017).

[22] Gorobtsov O Y, Mukharamova N, Lazarev S et al. Diffraction based Hanbury Brown and Twiss interferometry at a hard X-ray free-electron laser[J]. Scientific Reports, 8, 2219(2018).

[23] Brown R H, Twiss R Q. Interferometry of the intensity fluctuations in light III. Applications to astronomy[J]. Proceedings of the Royal Society of London Series a Mathematical and Physical Sciences, 248, 199-221(1958).

[24] [M]. The quantum theory of light, 118-124(1992).

     Loudon R, Loudon R[M]. 光的量子理论, 118-124(1992).

[25] [M]. Statistical optics, 15-28(1992).

     Goodman J W, Goodman J W[M]. 统计光学, 15-28(1992).

[26] Everitt B S, Skrondal A[M]. The Cambridge dictionary of statistics, 418-419(2010).

[27] Als-Nielsen J[M]. McMorrow D. Elements of modern X-ray physics, 17-18(2014).