Citation: | SEYEDABADI M E, FALANGA M, AZAM M, BARESI N, FLÉRON R, JANTARACHOTE V, JUAREZ ORTIZ V A, JULCA YAYA J J, LANGER M, MANUTHASNA S, MARTINOD N, MUGHAL M R, NOMAN M, PARK J, PIMNOO A, PRAKS J, REYNERI L, SANNA A, ŞIŞMAN T Ç, SOME J, ULAMBAYAR T, YU Xiaozhou, DONG Xiaolong, BALDIS L. Science Missions Using CubeSats[J]. Chinese Journal of Space Science, 2020, 40(4): 443-461. doi: 10.11728/cjss2020.04.443 |
[1] |
MILLAN R M, VON STEIGER R, ARIEL M, et al. Small satellites for space science[J]. Adv. Sp. Res., 2019, 64:1466-1517
|
[2] |
FLÉRON R. Will CubeSats introduce a MOORE's law to space science missions[J]. Adv. Astron. Sci., 2018, 163:677-694
|
[3] |
RUGGIERO M L, TARTAGLIA A. Test of gravitomagnetism with satellites around the Earth[J]. Eur. Phys. J. Plus, 2019, 134(5):205
|
[4] |
PALMROTH M, PRAKS J, VAINIO R, et al. FORESAIL-1 cubesat mission to measure radiation belt losses and demonstrate de-orbiting[J]. J. Geophys. Res. Space Phys., 2019, 124. DOI: 10.1029/2018JA026354
|
[5] |
IAKUBIVSKYI I, JANHUNEN P, PRAKS J, et al. Coulomb drag propulsion experiments of ESTCube-2 and FORESAIL-1[J]. Acta Astron., 2019. DOI:10.1016/j. actaastro.2019.11.030
|
[6] |
TWIGGS B. Origin of CubeSat//Small Satellites:Past, Present, and Future[M]. El Segundo California:Aerospace Press, 2008:151-173
|
[7] |
NATIONAL ACADEMIES OF SCIENCES, ENGINEERING, AND MEDICINE. Achieving Science with CubeSats:Thinking inside the Box[M]. Washington D C:National Academies Press, 2016
|
[8] |
CZECH M, FLEISCHNER A, WALTER U. A firstMOVE in Satellite Development at the TU-München//Small Satellite Missions for Earth Observation[M]. Berlin Heidelberg:Springer, 2010:235-245
|
[9] |
LANGER M, OLTHOFF C, DATASHVILI L, et al. Deployable structures in the CubeSat program MOVE[C]//Proceedings of the 2nd International Conference on Advanced Lightweight Structures and Reflector Antennas. Tbilisi, Georgia, 2014
|
[10] |
LANGER M, OLTHOFF C, HARDER J, et al. Results and lessons learned from the CubeSat mission FirstMOVE[M]//Small Satellite Missions for Earth Observation. Berlin Heidelberg:Springer, 2015
|
[11] |
LANGER M, SCHUMMER F, APPEL N, et al. MOVE-Ⅱ-The Munich Orbital Verification Experiment Ⅱ[C]//Proceedings of the 4th IAA Conference on University Satellite Missions and CubeSat Workshop. Rome:IAA, 2017:IAA-AAS-CU-17-06-05
|
[12] |
RUTZINGER M, KREMPEL L, SALZBERGER M, et al. On-orbit verification of space solar cells on the CubeSat MOVE-Ⅱ[C]//2016 IEEE 43rd Photovoltaic Specialists Conference (PVSC). Portland, OR, USA:IEEE, 2016:2605-2609
|
[13] |
MCCURDY H E. Faster, better, cheaper:low-cost innovation[M]//The U.S. Space Program. London:Johns Hopkins University Press, 2003
|
[14] |
BEARDEN D A. Small-Satellite Costs[R]. Crosslink Winter, 2000/2001:33
|
[15] |
MALPHRUS B. A new era of planetary exploration with small satellite platforms[C]//4th IAA Conference on University Satellite Missions and CubeSat Workshop. Rome:IAA, 2017
|
[16] |
RIZWAN MUGHAL M, ALI A, REYNERI L M. Plugand-play design approach to smart harness for modular small satellites[J]. Acta Astron., 2014, 94(2):754-764. DOI: 10.1016/j.actaastro.2013.09.015
|
[17] |
ALI A, RIZWAN MUGHAL M, ALI H, REYNERI L. Innovative power management, attitude determination and control tile for CubeSat standard NanoSatellites[J]. Acta Astron., 2014, 96:116-127. DOI: 10.1016/j.actaastro.2013.11.013.
|
[18] |
LANGER M, BOUWMEESTER J. Reliability of CubeSats-statistical data, developers' beliefs and the way forward[C]//Proceedings of the 30th Annual AIAA/USU Conference on Small Satellites. Logan, UT:AIAA, 2016:SSC16-X-2
|
[19] |
SWARTWOUT M. The first one hundred CubeSats:a statistical look[J]. J. Small Sat., 2013, 2(2):213-233
|