In this work, we have proposed a scattering spectra-based method for inverting the surface materials and material proportions of space objects (SOs) from long distances. The results of this work shall improve efforts to characterize and predict the orbits of space debris. We first constructed a physical model for SO characterization based on scattering spectra and then provided a least-squares solution with minimum-norm (LSMN) algorithm for inverting the surface materials and material proportions of an SO. The optical reflectance of complex material surfaces was characterized using a bidirectional reflectance distribution function (BRDF)-based multimodal fusion model that uses the characteristics of the light source, the reflectance of the target’s surface materials, and structures, and the angle of incidence and reflection. The area of each material in the BRDF was then treated as the to-be-inverted parameter. The proposed method was then experimentally validated using four sets of materials. The materials and proportions of equiproportional and non-equiproportional combinations of materials were inverted by the proposed method, and the average inversion error was less than 10%. According to the relationship curve be-tween experimental data error and inversion error, and between theoretical error and inversion error, it can be concluded that the accuracy of inversion error has a linear relationship with the measurement data error. In summary, we have provided a new technical approach for the inversion and characterization of SO materials and material proportions from long distances.
References
[1]
Zheng, S.-G. and Yan, J. (2014) Progress in Space Debris Protection Requirements and Protection Materials. Space International, No. 6, 49-53.
[2]
Chen, C.-Y., Wu, S.-B., Dong, X.-L., Zhang, H.-H. and Wei, M. (2017) Study of Material Testing Technology for Space Debris. Journal of Astronautic Metrology and Measurement, 37, 54-57.
[3]
Zeng, A.-L., Jin, Y., Ma, Z.-H., Han, L. and Gao, Y.-Q. (2019) Research on Early Warning Analysis and Display Technology of Space Debris Collision. Space Debris Research, 19, 21-27.
[4]
Li, S.-J., Gao, X.-D. and Zhu, Q.-X. (2004) Analysis for Luminosity Features of a Satellite with Solar Battery Panels. Opto-Electronic Engineering, 31, 1-8.
[5]
Li, B.-C. (1989) Optical Characteristic Analysis of Space Target. Optical Engineering, 80, 21-26.
[6]
Li, X.-Y., Gao, X.-D. and Zhu, Q.-X. (2003) Application of Vector Method to the Calculation of Space Target Ground Irradiance. Opto-Electronic Engineering, 30, 28-30.
[7]
Gao, Z.-S., Wang, Q. and Chen, J.-B. (1996) Model of Scattering from Non-Optical Surfaces in Optical System. Acta Photonica Sinica, 20, 457-460.
[8]
Fan, W., Wang, Y. and Rao, R.-Z. (2006) Wavelength Band Selection Method for Target Detection Considering Surface Reflectivity. Acta Photonica Sinica, 35, 755-759.
[9]
Che, C.-C., Li, Y.-C., Chen, R.-L., Fan, X.-W. and Ma, Z. (2007) Research on Feasibility of GEO Target Visual Detection. Acta Photonica Sinica, 36, 905-908.
https://doi.org/10.4028/www.scientific.net/KEM.334-335.905
[10]
Xu, J.-B., Jiang, Z.-D., Zhao, Y.-L. and Song, K. (2006) Simulation on the Scattering from Fractal Rough Surface with Multi-Light Beam. Acta Photonica Sinica, 35, 1925-1929.
[11]
Rovetto, R.J. (2016) Proceedings of the Advanced Maui Optical and Space Surveillance Technologies (AMOS) Conference.
[12]
Alcala, C.M. and Brown, J.H. (2009) Space Object Characterization Using Time-Frequency Analysis of Multi-spectral Measurements from the Magdalena Ridge Observatory. Journal of Bone & Joint Surgery British Volume, 92, 169-175.
https://doi.org/10.1302/0301-620X.92B1.22629
[13]
Diao, H.-F. and Li, Z. (2010) Research on the Identification of Geo-synchronous Objects with Space-Based Visible Surveillance Data. Journal of the Academy of Equipment Command & Technology, 5.
[14]
Linares, R., Shoemaker, M., Palmer, D.M., Thompson, D.C. and Koller, J. (2014) Photometric Data from Non-Resolved Objects for Space Object Characterization and Improved Atmospheric Modeling. Advances in the Astronautical Sciences, 152, 1889-1899.
[15]
Wetterer, C.J. and Jah, M. (2009) Attitude Estimation from Light Curves. Journal of Guidance Control & Dynamics., 32, 1648-1651. https://doi.org/10.2514/1.44254
