Study on Laser Ranging for Satellite on the Second Lagrange Point of Earth-Moon System
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摘要:
介绍了月球/中继星激光测距的科学意义、研究状况和发展趋势;研究了地月第二拉格朗日点(L2点)纯反射式激光测距技术和任务设计,主要包含单体大孔径激光角锥反射器的设计与研制,以及基于云南天文台1.2 m望远镜的月球/中继星激光测距系统研究。研究结果表明:采用单脉冲能量3 J和10 ns脉宽脉冲激光器,预期系统能接收到的单脉冲回波光电子数约为0.74,单光子测距精度优于1 m。
Abstract:The background and scientific goals of lunar/relay-satellite laser ranging is introduced. The current status and development trends of laser ranging is presented. The mission design is discussed,mainly including the manufacture of a single 170-mm-aperture Corner-Cube Retroreflector(CCR)a the laser ranging system based on a 1.2-m telescope installed at the Kunming station of Yunnan Observatory. A pulse laser with pulse width of 10ns and pulse energy of 3 J is used. The received photon number of 0.74 is expected,and the ranging precision is better than 1 meter.
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[1] Currie D,Dell'Agnello S,Monache G. A lunar laser ranging retroreflector array for the 21st century[J]. Acta Astronautica,2011,68:667-680. [2] Turyshev S,Williams J,Folkner W,et al. Corner-cube retro-reflector instrument for advanced lunar laser ranging[J]. Experimental Astronomy,2013,36:105-135. [3] Dickey J,Bender P,Faller J,et al. Lunar laser ranging:a continuing legacy of the Apollo program[J]. Science,1994,265:482-490. [4] Murphy T,Adelberger E,Strasburg J,et al. Testing gravity via next-generation lunar laser-ranging[J]. Nuclear Physics B(Proceedings Supplements),2004,134:155-162. [5] Murphy T. Lunar laser ranging:the millimeter challenge[J]. Reports on Progress in Physics,2013,76,076901. [6] Williams J,Boggs D,Yoder C,et al. Lunar rotational dissipation in solid body and molten core[J]. Journal of Geophysics Research,2001,106:27933-68. [7] Khan A,Mosegaard K,Williams J,et al. Does the Moon possess a molten core? probing the deep lunar interior using results from LLR and Lunar Prospector[J]. Journal of Geophysics Research,2004,109,E09007. [8] 于登云,吴学英,吴伟仁. 我国探月工程技术发展综述[J]. 深空探测学报,2016,3(4):307-314.Yu D Y,Wu X Y,Wu W R. Review of technology development for Chinese Lunar Exploration Program[J]. Journal of Deep Space Exploration,2016,3(4):307-314. [9] 叶培建,于登云,孙泽洲,等. 中国月球探测器的成就与展望[J]. 深空探测学报,2016,3(4):323-333.Ye P J,Yu D Y,Sun Z Z,et al. Achievements and prospect of Chinese lunar probes[J]. Journal of Deep Space Exploration,2016,3(4):323-333. [10] 吴伟仁,崔平远,乔栋,等. 嫦娥二号日地拉格朗日L2点探测轨道设计与实施[J]. 科学通报,2012,21:1987-1991.Wu W R,Cui P Y,Qiao D,et al. Design and performance of exploring trajectory to Sun-Earth L2 point for Chang'E-2 mission[J]. Chinese Science Bulletin,2012,21:1987-1991. [11] 吴伟仁,罗辉,谌明,等. 面向日地拉格朗日L2点探测的深空要测数传系统设计与试验[J]. 系统工程与电子技术,2012,34(12):2559-2563.Wu W R,Luo H,Chen M,et al. Design and experiment of deep space telemetry and data transmission system in Libration points 2 exploring[J]. Systems Engineering and Electronics,2012,34(12):2559-2563. [12] Gurtner W,Noomen R,Pearlman M. The International laser ranging service:current status and future developments[J]. Advances in Research,2005,36:327-332. [13] John D. SLR2000 Project:engineering overview and status[C]//The 11th International Workshop on Laser Ranging. Deggendorf,Germany:[s.n.],1998. [14] Kirchner G,Koidl F. Graz kHz SLR system:design,experiences and results[C]//The 14th International Workshop on Laser Ranging. Fernondo,Spain:[s.n.],2004. [15] Zhang Z,Zhang H,Meng W,et al. Chinese SLR network and its contributions to the sub-network of GGOS in China[C]//EGU General Assembly Conference. Vienna,Austria:EGU,2015. [16] Chin G,Brylow S,Foote M,et al. Lunar Reconnaissance Orbiter overview:the instrument suite and mission[J]. Space Science Reviews,2007,129:391-419. [17] Bauer S,Hussmann H,Oberst J,et al. Demonatration of orbit determination for the Lunar Reconnaissance Orbiter using one-way laser ranging data[J]. Planetary and Space Science,2016,129:32-46. [18] Mao D,McGarry J,Mazarico E,et al. The laser ranging experiment of the Lunar Reconnaissance Orbiter:Five years of operations and data analysis[J]. Icarus,2017,283:55-69. [19] Dell'Agnello S,Monache G,Porcelli L,et al. INRRI-EDM/2016:the first laser retroreflector on the surface of Mars[J]. Advances in Space Research,2017,59(2):645-655. [20] Mizuno T,Kase T,Shiina T,et al. Development of the Laser Altimeter(LIDAR) for Hayabusa2[J]. Space Science Review,2016,1-15,doi:10.1007/s11214-015-0231-2. [21] Noda H,Kunimori H,Mizuno T,et al. Laser link experiment between Hayabusa2 laser altimeter and SLR stations[C]//The 20th International Workshop on Laser Ranging. Potsdam,Germany:[s.n.],2016. [22] Murphy T,Adelberger E,Battat J,et al. APOLLO performance and data quality[C]//Proceedings of the 19th International Workshop on Laser Ranging. Annapolis,Maryland:[s.n.],2014. [23] He Y,Liu Q,Duan H,et al. A 170 mm hollow corner cube retro-reflector on Chang'e 4 lunar relay satellite[C]//The 20th International Workshop on Laser Ranging. Potsdam,Germany:[s.n.],2016. [24] Faller J,Alley C,Bender P,et al. Laser ranging retroreflector[R]. USA:Apollo 15:Preliminary Science Report,1971. [25] Murphy T,Adelberger E,Battat J,et al. Long-term degradation of optical devices on the Moon[J]. Icarus,2010,208:31-35. [26] 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,2016,68(101):1-12. [27] Otsubo T,Kunimori H,Noda H,et al. Simulation of optical response of retroreflectors for future lunar laser ranging[J]. Advances in Space Research,2010,45:733-740. [28] Preston A,Merkowitz S. Comparison of fabrication techniques for hollow retroreflectors[J]. Optical Engineering,2014,53(6),065107:1-7. [29] Preston A,Merkowitz S. Next-generation hollow retroreflectors for lunar laser ranging[J]. Applied Optics,2013,52(36):8676-8684. [30] Marini J,Murray C. Correction of laser range tracking data for atmospheric refraction at elevations above 10 degrees[R]. USA:NASA Technical Memorandum,NASA-TM-X-70555,1973. -
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