[13] W P JONES, J R WATKINS, T A CALVERT. Temperatures and Thermophysical Properties of the Lunar Outermost Layer. The moon, 13, 475-494(1975).

[14] S S SCHREINER, J A DOMINGUEZ, L SIBILLE et al. Thermophysical Property Models for Lunar Regolith. Advances in Space Research, 57, 1209-1222(2016).

[15] R B MALLA, K M BROWN. Determination of Temperature Variation on Lunar Surface and Subsurface for Habitat Analysis and Design. Acta Astronautica, 107, 196-207(2015).

[16] B MOSELEY, V BICKEL, J BURELBACH et al. Unsupervised Learning for Thermophysical Analysis on the Lunar Surface. The Planetary Science Journal, 1, 32(2020).

[17] Z ZHONG, J G YAN, Z Y XIAO. Lunar Regolith Temperature Variation in the Rümker Region Based on the Real-Time Illumination. Remote Sensing, 12, 731(2020).

[18] E GRÜN, H A ZOOK, H FECHTIG et al. Collisional Balance of the Meteoritic Complex. Icarus, 62, 244-272(1985).

[19] MOHEAD A V, KOEHLER H M, COOKE W J. NASA Meteoid Engineering Model Release 2.0: NASATM—2015–218214[R]. Huntsville, Alabama: Marshall Space Flight Center, 2015.

[20] SUGGS R J, SUGGS R M. Results of Lunar Impact Observations During Geminid Mete Shower Events: M1398[R]. Alabama, USA: Marshall Space Flight Center, 2015.

[21] ZHANG H, CAO J B, LIN Y T, et al. Key Questions of Solar WindMoon Interaction[J]. Space: Science & Technology, 2023, 3(8): 0060. DOI: 10.34133space.0060.

[22] J S HALEKAS, G T DELORY, D A BRAIN et al. Density Cavity Observed Over a Strong Lunar Crustal Magnetic Anomaly in the Solar Wind: a Mini-magnetosphere?. Planetary and Space Science, 56, 941-946(2008).

[24] S MOTTAGHI, H BENAROYA. Design of a Lunar Surface Structure. II: Seismic Structural Analysis. Journal of Aerospace Engineering, 28, 04014053(2015).

[26] H BENAROYA. Lunar Habitats: A Brief Overview of Issues and Concepts. Reach, 7/8, 14-33(2017).

[28] CADOGAN D, SCHEIR C. Expable Habitat Technology DemonStration f Lunar Antarctic Applications[C]38th International Conferenceon Environmental Systems, June 29July 2, 2008, San Francisco, Califnia. Pennsylvania, USA: SAE, 2008: 314. DOI: 10.42712008012024.

[30] LITTEKEN D, SELIG M, VALLE G, et al. Utilizing Photogrammetry Strain Gage Measurement to acterize Pressurization of an Inflatable Module[C]53rd Structures, Structural Dynamics, Materials Conference, April 23, 2012, Honolulu, Hawaii. Menlo Park, CA: AIAA, 2012: 1913. DOI: 10.25146.20121913.

[31] PABLO D L, REW D, IRENE S, et al. Design Construction of an Inflatable Lunar Base with Pressurized Rovers Suit Pts[C]61st International Astronautical Congress, September 27October 1, 2010, Prague, Czech. [S.l.]: [s.n.], 2010: 29.

[32] HAEUPLIK M S, OZDEMIR K. Deployable Lunar Habitation Design[M]. Berlin, Heidelberg: Springer, 2012. DOI: 10.10079783642279690_20.

[33] HINKLE J, DIXIT A, LIN J, et al. Design Development Testing f an Expable Lunar Habitat[C]AIAA SPACE 2008 Conference & Exposition, September 911, 2008, San Diego, Califnia. Menlo Park, CA: AIAA, 2008: 7634. DOI: 10.25146.20087634.

[34] MARC M C. ed Precepts in Lunar Architecture[C]34th COSPAR Scientific Assembly, The Second Wld Space Congress, October 1019, 2002, Houston, TX, USA. [S.l.]: NASA, 2002: Q4308.

[35] BELVIN W K, WASTON J J, SINGHAL S N. Structural Concepts Materials f Lunar Explation Habitats[C]AIAA Space 2006 Conference Exposition, June 18, 2012, San Jose, Califnia. Califnia. Menlo Park, CA: AIAA. 2006: 7338. DOI: 10.25146.20067338.

[36] RAIS R M. On Structural Design of a Mobile Lunar Habitat with MultiLayered Environmental Shielding: 20050185204[R]. Mississippi State: Mississippi State University Department of Aerospace Engineering, 2005.

[37] F L WHIPPLE. Meteorites and Space Travel. The Astronomical Journal, 52, 131(1947).

[38] F W KE, J HUANG, X Z WEN et al. Study on Shield Configuration Stuffed With the Integrated Fabric Layer and Its Bracing Structure. International Journal of Impact Engineering, 121, 191-202(2018).

[39] F W KE, J HUANG, X Z WEN et al. Test Study on the Performance of Shielding Configuration With Stuffed Layer Under Hypervelocity Impact. Acta Astronautica, 127, 553-560(2016).

[40] E L CHRISTIANSEN, J H KERR. Projectile Shape Effects on Shielding Performance at 7 km/s and 11 km/s. International Journal of Impact Engineering, 20, 165-172(1997).

[41] M B BOSLOUGH, Ja ANG, L C CHHABILDAS et al. Hypervelocity Testing of Advanced Shielding Concepts for Spacecraft Against Impacts to 10 km/s. International Journal of Impact Engineering, 14, 95-106(1993).

[42] WALLER J M, ROJDEV K, SHARIFF K, et al. Simulated Galactic Cosmic Ray Solar Particle Event Radiation Effects on Inflatable Habitat, Composite Habitat, Space Suit Space Hatch Cover Materials: 20200003125[R]. Houston, Texas: Johnson Space Center, 2020.

[43] WOODARD S, TAYL B, JONES T, et al. Method to have MultiLayer Thermal Insulation Provide Damage Detection[C]48th AIAAASMEEAHS Structures, Tructural Dynamics, Materials Conference, April 2326, 2007, Waikiki, HI. Califnia. Menlo Park, CA: AIAA, 2007: 1847.

[44] E J BRANDON, M VOZOFF, E A KOLAWA et al. Structural Health Management Technologies for Inflatable/Deployable Structures: Integrating Sensing and Self-healing. Acta Astronautica, 68, 883-903(2011).

[47] ZHANG Z F, MU Q Z, CUi X, et al. Distribution Room Modeling Based on Digital Twin[C]2023 International Conference on Computer Applications Technology (CCAT). September 1517, 2023, Guiyang, China. Piscataway, NJ: IEEE, 2023: 712. DOI: 10.1109CCAT59108.2023.00009.

[48] A KAMPKER, H H HEIMES, B DORN et al. Concept for Digital Product Twins in Battery Cell Production. World Electric Vehicle Journal, 14, 108(2023).