[1] Ye S H, Huang C[M]. Astrodynamics(2000).

[2] Dickey J O, Bender P L, Faller J E et al. Lunar laser ranging: a continuing legacy of the Apollo program[J]. Science, 265, 482-490(1994).

[3] Murphy T W. Lunar laser ranging: the millimeter challenge[J]. Reports on Progress in Physics, 76, 076901(2013).

[4] Currie D, Dell’Agnello S, Monache G D. A lunar laser ranging retroreflector array for the 21st century[J]. Acta Astronautica, 68, 667-680(2011).

[5] Martini M, Dell’Agnello S, Currie D et al. MoonLIGHT: a USA-Italy lunar laser ranging retroreflector array for the 21st century[J]. Planetary and Space Science, 74, 276-282(2012).

[6] Araki H, Kashima S, Noda H et al. Thermo-optical simulation and experiment for the assessment of single, hollow, and large aperture retroreflector for lunar laser ranging[J]. Earth, Planets and Space, 68, 1-12(2016).

[7] Liu Q, He Y, Duan H Z et al. Progress on the design of retroreflector for lunar laser ranging[J]. Acta Scientiarum Naturalium Universitatis Sunyatseni, 60, 239-246(2021).

[8] Zhou H, Li S, Zheng G X et al. Effective diffraction region for satellite retroreflector[J]. Acta Photonica Sinica, 38, 1920-1925(2009).

[9] Fienga A, Deram P, Viswanathan V et al. INPOP19a planetary ephemerides[J/OL]. Notes Scientifiques et Techniques de l’Institut de Mecanique Celeste, 109(2019).

[10] Liang Q T[M]. Physical optics(2011).

[11] Li Y Q, Fu H L, Li R W et al. Research and experiment of lunar laser ranging in Yunnan observatories[J]. Chinese Journal of Lasers, 46, 0104004(2019).

[12] Pi X Y, Fu H L, Zhai D S et al. Study on transmitting/echo signal overlapping in common-optical-path 100 Hz-rate LLR system[J]. Infrared and Laser Engineering, 49, 20190467(2020).

[13] Rao R Z. Discussion on some key physical and technical problems about lunar laser ranging[J]. Acta Optica Sinica, 41, 0112002(2021).

[14] Golub G. Numerical methods for solving linear least squares problems[J]. Numerische Mathematik, 7, 206-216(1965).