Citation: | WANG Lianguo, ZHU Yan, ZHOU Changyi, AN Junshe, RAO Jianing. Integrated Payload OBDH Technology for Deep Space Exploration[J]. Chinese Journal of Space Science, 2018, 38(6): 960-970. doi: 10.11728/cjss2018.06.960 |
[1] |
TOMAS DE, JMATEO SANGUINO. 50 years of rovers for planetary exploration: a retrospective review for future directions[J]. Robot. Auton. Syst., 2017, 94:172-185
|
[2] |
XIN Hua. China will implement four major deep space missions in the future[J]. Space Exploration, 2017(03):5 (新华. 中国未来将实施四次重大深空探测任务[J]. 太空探索, 2017(3):5)
|
[3] |
SUN Zezhou, MENG Linzhi. Current situation and sustainable development trend of deep space exploration in China[J]. J. Nanjing Univ. Aeron. Astron., 2015, 47(6):785-91 (孙泽洲, 孟林智. 中国深空探测现状及持续发展趋势[J]. 南京航空航天大学学报, 2015, 47(6):785-91)
|
[4] |
ZHANG Meng, MENG Linzhi, HUANG Jiangchuan, et al. Design and implementation of Chang'E satellite's high reliable electronic information system based on multilevel control structure[J]. Sci. Sin: Technol., 2013, 43(7):739-747 (张猛, 孟林智, 黄江川, 等. 基于多级控制结构的嫦娥卫星高可靠电子信息体制设计与实现[J]. 中国科学: 技术科学, 2013, 43(7):739-747)
|
[5] |
CHEN J X, ZHANG Z, WANG L, et al. Design and realization of the integrated electronic system for the Chang'E-3 lunar rover[J]. Sci. Sin. Tech., 2014, 44(5):450-460 (陈建新, 张志, 王磊, 等. 嫦娥三号巡视器综合电子系统的设计与实现[J]. 中国科学: 技术科学, 2014, 44(5):450-460)
|
[6] |
SUN H X, DAI S W. Mission objectives and payloads for the first lunar exploration of China[J]. Acta Astron., 2005, 57(2-8):561-565
|
[7] |
CHEN Xiaomin, SUN Huixian. Payload OBDH system of Chang'E-1 satellite[C]//The 18th. academy meeting of Space exploration professional committee of China space science society. Sanxia: Chinese Society of Space Science, 2005 (陈小敏, 孙辉先. 嫦娥一号卫星有效载荷数据管理系统[C]//中国空间科学学会空间探测专业委员会第十八次学术会议论文集. 三峡: 中国空间科学学会, 2005)
|
[8] |
WU W R, WANG Q, TANG Y H, et al. Design of Chang'E-4 lunar farside soft-landing mission[J]. J. Deep Space Explor., 2017, 4(2):111-117 (吴伟仁, 王琼, 唐玉华, 等. "嫦娥4号"月球背面软着陆任务设计[J]. 深空探测学报, 2017, 4(2):111-117)
|
[9] |
DAI Shuwu, WU Ji, SUN Huixian, et al. Chang'E-3 lunar rover's scientific payloads[J]. Chin. J. Space Sci., 2014, 34(3):332-340 (代树武, 吴季, 孙辉先, 等. 嫦娥三号巡视器有效载荷[J]. 空间科学学报, 2014, 34(3):332-340)
|
[10] |
JIA Yingzhuo, DAI Shuwu, WU Ji, et al. Chang'E-3 Lander's scientific payloads[J]. Chin. J. Space Sci., 2014, 34(2):219-225 (贾瑛卓, 代树武, 吴季, 等. 嫦娥三号着陆器有效载荷[J]. 空间科学学报, 2014, 34(2):219-225)
|
[11] |
ZHOU Li, AN Junshe, XIE Yan, et al. Design of a 1553B IP core based on ASIC technology[J]. Chin. J. Space Sci., 2014, 34(1):127-136 (周莉, 安军社, 谢彦, 等. 基于ASIC 技术的1553B IP核的设计[J]. 空间科学学报, 2014, 34(1):127-136)
|
[12] |
ZHOU Li, AN Junshe. Design of a RS485-to-1553B bus bridge[C]//2013 International Conference on Cyber-Enabled Distributed Computing and Knowledge Discovery. Beijing: IEEE Computer Society, 2013:255-258
|
[13] |
VLADIMIROVA T, FAYYAZ M, SWEETING M N, et al. A novel autonomous low-cost on-board data handling architecture for a pin-point planetary lander[J]. Acta Astron., 2011, 68(7/8):811-829
|
[14] |
IMKEN T, CASTILLO-ROGEZ J, HE Y, et al. CubeSat flight system development for enabling deep space science[C]//2017 IEEE Aerospace Conference. Big Sky, MT: IEEE, 2017:1-14
|
[15] |
GR740-UM-DS[OL]. Aeroflex. [2017-01-01]. https://www.gaisler.com/doc/gr740/GR740-UM-DS.pdf
|
[16] |
YE Hao. Compressed Sensing Based Compression and Reconstruction of Deep Space Image[D]. Chongqing: Chongqing University of Posts and Telecommunications, 2016 (叶浩. 基于压缩感知的深空图像压缩采样与恢复算法研究[D]. 重庆: 重庆邮电大学, 2016)
|
[17] |
LIU Yunlu. Research on Image Compression Based on Compressed Sensing in the Deep Space[D]. Harbin Institute of Technology, 2015 (刘云路. 基于压缩感知的深空探测图像压缩研究[D]. 哈尔滨工业大学, 2015)
|
[18] |
CUI P Y, XU R, ZHU S Y, et al. State of the art and development trends of on-board autonomy technology for deep space explorer[J]. Acta Aeron. Astron. Sin., 2014, 35(1):13-28 (崔平远, 徐瑞, 朱圣英, 等. 深空探测器自主技术发展现状与趋势[J]. 航空学报, 2014, 35(1):13-28)
|
[19] |
CASTANO A, FUKUNAGA A, BIESIADECKI J, et al. Automatic detection of dust devils and clouds on Mars[J]. Mach. Vision Appl., 2008, 19(5/6):467-482
|
[20] |
ESTLIN T A, BORNSTEIN B J, GAINES D M, et al. AEGIS automated targeting for MER opportunity rover[J]. Acm Trans. Intell. Syst. Tech., 2012, 3(3):1-16
|
[21] |
FRANCIS R, ESTLIN T, GAINES D, et al. AEGIS intelligent targeting deployed for the Curiosity Rover's ChemCam instrument[C]//Lunar and Planetary Science Conference. The Woodlands, Texas, 2016
|
[22] |
FRANCIS R, Estlin T, Gaines D, et al. AEGIS autonomous targeting for the Curiosity rover's ChemCam instrument[C]//2016 IEEE Applied Imagery Pattern Recognition Workshop (AIPR). Washington D C: IEEE, 2016:1-4
|
[23] |
GANKIDI P R, THANGAVELAUTHAM J. FPGA architecture for deep learning and its application to planetary robotics[C]//2017 IEEE Aerospace Conference. Big Sky MT: IEEE, 2017:1-9
|