Abstract
On May 15, 2021, Tianwen-1 successfully landed in the Utopia Planitia of Mars, and its rover Zhurong began to carry out an in-situ science exploration of the Mars surface. To determine the location, driving direction, and exploration targets of the rover, it is necessary to provide decision support for the in-situ science exploration of the rover and ensure the achievement of the scientific objectives, which pose significant challenges to the ground science team. Based on the classical research on Lunar and planetary localization, navigation and exploration target selection, and the recent study of pan-location cartographic theory, a pan-location mapping method for an in-situ rover exploration is proposed. In addition, a pan-location reference system, mapping data model, and mapping method are designed to realize the localization and visualization of the landing platform, rover, and exploration targets. The mapping method has been successfully applied to the localization, navigation, and science exploration of the target selection involved in the in-situ exploration of the Zhurong rover. The results of this study not only provide vital support to the implementation of the Tianwen-1 mission; they can also be used as instructions for other future in-situ Lunar and planetary exploration missions.
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References
Liu J J, Li C L, Zhang R Q, et al. Geomorphic contexts and science focus of the Zhurong landing site on Mars. Nat Astron, 2022, 6: 65–71
Wan W, Yu T, Di K, et al. Visual localization of the Tianwen-1 lander using orbital, descent and rover images. Remote Sens, 2021, 13: 3439
Li R, Squyres S W, Arvidson R E, et al. Initial results of rover localization and topographic mapping for the 2003 Mars exploration rover mission. Photogramm Eng Remote Sens, 2005, 71: 1129–1142
Li R, Archinal B A, Arvidson R E, et al. Spirit rover localization and topographic mapping at the landing site of Gusev crater, Mars. J Geophys Res, 2006, 111: E02S06
Li R, Arvidson R E, Di K, et al. Opportunity rover localization and topographic mapping at the landing site of Meridiani Planum, Mars. J Geophys Res, 2007, 112: E02S90
Liu J J, Ren X, Yan W, et al. Descent trajectory reconstruction and landing site positioning of Chang’E-4 on the Lunar farside. Nat Commun, 2019, 10: 4229
Parker T J, Malin M C, Calef F J, et al. Localization and contextualization of Curiosity in Gale Crater, and other landed Mars missions. In: Proceedings of Lunar and Planetary Science Conference, 2013
Williams N R, Stack K M, Calef III F J, et al. Photo-geologic mapping of the Mars 2020 landing site, Jezero Crater, Mars. In: Proceedings of the 51st Lunar and Planetary Science Conference, Houston, 2020
Olson C F. Probabilistic self-localization for mobile robots. IEEE Trans Robot Automat, 2000, 16: 55–66
Olson C F, Matthies L H, Schoppers M, et al. Rover navigation using stereo ego-motion. Robotics Autonomous Syst, 2003, 43: 215–229
Liu Z Q, Di K C, Li J, et al. Landing site topographic mapping and rover localization for Chang’e-4 mission. Sci China Inf Sci, 2020, 63: 140901
Liu Z Q, Di K C, Peng M, et al. High precision landing site mapping and rover localization for Chang’e-3 mission. Sci China-Phys Mech Astron, 2015, 58: 019601
Di K C. Present situation of rover positioning and mapping technology and suggestions for the development of Lunar/Mars Rover positioning and mapping technology in China (in Chinese). J Remote Sensing, 2009, 13: 101–112
Zeng X G, Zuo W, Gao X, et al. In-situ exploration data positioning of Chang’e-4 rover with transverse route mapping. In: Proceedings of the 5th Planetary Data Workshop and Planetary Science Informatics and Data Analytics (PSIDA), 2021
Zeng X G, Mu L L. Lunar spatial environmental indicators dynamically modeling based exploration area selection (in Chinese). Geomat Inf Sci Wuhan Univ, 2017, 42: 91–96
Lv G N, Yuan L W, Yu Z Y. Surveying and mapping geographical information from the perspective of geography (in Chinese). Acta Geodaetica et Cartographica Sin, 2017, 46: 1549–1556
Zhou C H, Zhu X Y, Wang M, et al. Panoramic location-based map (in Chinese). Progress In Geography, 2011, 30: 1331–1335
Zhou C H. The era of pan-location map has come — the historical evolution of map function (in Chinese). Sci Surv Mapping, 2014, 39: 3–8
Zhu X Y, Zhou C H, Guo W, et al. Preliminary study on conception and key technologies of the location-based pan-information map (in Chinese). Geomat Inf Sci Wuhan Univ, 2015, 40: 285–295
Ma C, Arias E F, Eubanks T M, et al. The international celestial reference frame as realized by very long baseline interferometry. Astron J, 1998, 116: 516–546
Acton J C H. Ancillary data services of NASA’s navigation and ancillary information facility. Planet Space Sci, 1996, 44: 65–70
Acton C, Bachman N, Semenov B, et al. A look towards the future in the handling of space science mission geometry. Planet Space Sci, 2018, 150: 9–12
Folkner W M, Williams J G, Boggs D H. The Planetary and Lunar Ephemeris DE 421. Interplanetary Network Progress Report, 2009
Statella T. Mapping Mars: geodetic and cartographic aspects. Planet Space Sci, 2015, 108: 1–12
Zeng W F, Li S S, Wang J A. Translation, rotation and scaling changes in image registration based affine transformation model (in Chinese). Infrared Laser Eng, 2001, 30: 18–20
Hua Y X, Zhou C H. Description frame of data model of multi-granularity spatio-temporal object for pan-spatial information system (in Chinese). J Geo-Inform Sci, 2017, 19: 1142–1149
Williams D R. Viking mission to Mars. 2018. https://nssdc.gsfc.nasa.gov/planetary/viking.html
Dickson, Kerber L A, Fassett C I, et al. A global, blended CTX mosaic of Mars with vectorized seam mapping: a new mosaicking pipeline using principles of non-destructive image editing. In: Proceedings of the 49th Lunar and Planetary Science Conference, 2018
Fergason R L, Hare T M, Laura J. HRSC and MOLA blended digital elevation model at 200 m v2. Astrogeology PDS Annex, U.S. Geological Survey. 2018. http://bit.ly/HRSC_MOLA_Blend_v0
Liang X, Chen W L, Cao Z X, et al. The navigation and terrain cameras on the Tianwen-1 Mars rover. Space Sci Rev, 2021, 217: 37
Gao X Y, Liu J J, Ren X, et al. Research and implementation of a visual simulation system of orbit motion of Chang’E-2 spacecraft (in Chinese). Astron Res Tech, 2012, 9: 114–120
Gao X Y, Liu J J, Ren X, et al. Design and implementation of immersive virtual environment of the Moon based on Change’E-3 data of panoramic camera (in Chinese). J Comput-Aided Design Comput Graph, 2016, 28: 526–532
Zou Y, Zhu Y, Bai Y, et al. Scientific objectives and payloads of Tianwen-1, China’s first Mars exploration mission. Adv Space Res, 2021, 67: 812–823
Acknowledgements
This work was supported by China’s Planetary Exploration Program (Tianwen-1 mission), National Natural Science Foundation of China (Grant Nos. 11941002, 11803056), and Key Research Program of Chinese Academy of Sciences (Grant No. ZDBS-SSW-TLC001). The authors extend their gratitude for the engineering parameters provided by the probe system team of China Academy of Space Technology. The authors are also grateful to anonymous reviewers for their constructive suggestions.
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Zeng, X., Liu, J., Ren, X. et al. Pan-location mapping and localization for the in-situ science exploration of Zhurong Mars rover. Sci. China Inf. Sci. 65, 172201 (2022). https://doi.org/10.1007/s11432-021-3484-2
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DOI: https://doi.org/10.1007/s11432-021-3484-2