Hayabusa2 Landing Site Selection: Surface Topography of Ryugu and Touchdown Safety

Shota Kikuchi; Sei ichiro Watanabe; Takanao Saiki; Hikaru Yabuta; Seiji Sugita; Tomokatsu Morota; Naru Hirata; Naoyuki Hirata; Tatsuhiro Michikami; Chikatoshi Honda; Yashuhiro Yokota; Rie Honda; Naoya Sakatani; Tatsuaki Okada; Yuri Shimaki; Koji Matsumoto; Rina Noguchi; Yuto Takei; Fuyuto Terui; Naoko Ogawa; Kent Yoshikawa; Go Ono; Yuya Mimasu; Hirotaka Sawada; Hitoshi Ikeda; Chikako Hirose; Tadateru Takahashi; Atsushi Fujii; Tomohiro Yamaguchi; Yoshiaki Ishihara; Tomoki Nakamura; Kohei Kitazato; Koji Wada; Shogo Tachibana; Eri Tatsumi; Moe Matsuoka; Hiroki Senshu; Shingo Kameda; Toru Kouyama; Manabu Yamada; Kei Shirai; Yuichiro Cho; Kazunori Ogawa; Yukio Yamamoto; Akira Miura; Takahiro Iwata; Noriyuki Namiki; Masahiko Hayakawa; Masanao Abe; Satoshi Tanaka; Makoto Yoshikawa; Satoru Nakazawa; Yuichi Tsuda

doi:10.1007/s11214-020-00737-z

Hayabusa2 Landing Site Selection: Surface Topography of Ryugu and Touchdown Safety

Shota Kikuchi, Sei ichiro Watanabe, Takanao Saiki, Hikaru Yabuta, Seiji Sugita, Tomokatsu Morota, Naru Hirata, Naoyuki Hirata, Tatsuhiro Michikami, Chikatoshi Honda, Yashuhiro Yokota, Rie Honda, Naoya Sakatani, Tatsuaki Okada, Yuri Shimaki, Koji Matsumoto, Rina Noguchi, Yuto Takei, Fuyuto Terui, Naoko OgawaKent Yoshikawa, Go Ono, Yuya Mimasu, Hirotaka Sawada, Hitoshi Ikeda, Chikako Hirose, Tadateru Takahashi, Atsushi Fujii, Tomohiro Yamaguchi, Yoshiaki Ishihara, Tomoki Nakamura, Kohei Kitazato, Koji Wada, Shogo Tachibana, Eri Tatsumi, Moe Matsuoka, Hiroki Senshu, Shingo Kameda, Toru Kouyama, Manabu Yamada, Kei Shirai, Yuichiro Cho, Kazunori Ogawa, Yukio Yamamoto, Akira Miura, Takahiro Iwata, Noriyuki Namiki, Masahiko Hayakawa, Masanao Abe, Satoshi Tanaka, Makoto Yoshikawa, Satoru Nakazawa, Yuichi Tsuda

SCI - Earth Science

Research output: Contribution to journal › Article › peer-review

16 Citations (Scopus)

Abstract

One of the primary goals of Hayabusa2 is to land on the asteroid Ryugu to collect its surface materials. The key for a successful touchdown is to find a promising landing site that meets both scientific and engineering requirements. Due to the limited availability of pre-arrival information about Ryugu, the landing site selection (LSS) must be conducted based on proximity observations over a limited length of time. In addition, Ryugu was discovered to possess an unexpectedly high abundance of boulders with an absence of wide and flat areas, further complicating the LSS. To resolve these problems, we developed a systematic and stepwise LSS process with a focus on the surface topography of Ryugu and the associated touchdown safety. The proposed LSS scheme consists of two phases: Phase-I LSS, a comprehensive survey of potential landing areas at the 100-m scale based on the global mapping of Ryugu, and Phase-II LSS, a narrowing-down process of the candidate landing sites at the 10-m scale using high-resolution images and a local terrain model. To verify the feasibility of a precision landing at the target site, we also investigated the landing dispersion via a Monte Carlo simulation, which incorporates the effect of the irregular surface gravity field. One of the major characteristics of the Hayabusa2 LSS developed in this study is the iterative feedback between LSS analyses on the ground and actual spacecraft operations near the target asteroid. Using the newly developed method, we chose a landing site with a radius of 3 m, and Hayabusa2 successfully conducted its first touchdown on February 21, 2019. This paper reports the methodology and results of the stepwise iterative LSS for the first Hayabusa2 touchdown. The touchdown operation results reconstructed from flight data are also provided, demonstrating the validity of the adopted LSS strategy.

Original language	English
Article number	116
Journal	Space Science Reviews
Volume	216
Issue number	7
DOIs	https://doi.org/10.1007/s11214-020-00737-z
Publication status	Published - 2020 Oct 1

Keywords

Asteroid exploration
Landing site selection
Pinpoint touchdown
Spacecraft safety
Terrain map

ASJC Scopus subject areas

Astronomy and Astrophysics
Space and Planetary Science

Access to Document

10.1007/s11214-020-00737-z

Cite this

Kikuchi, S., Watanabe, S. I., Saiki, T., Yabuta, H., Sugita, S., Morota, T., Hirata, N., Hirata, N., Michikami, T., Honda, C., Yokota, Y., Honda, R., Sakatani, N., Okada, T., Shimaki, Y., Matsumoto, K., Noguchi, R., Takei, Y., Terui, F., ... Tsuda, Y. (2020). Hayabusa2 Landing Site Selection: Surface Topography of Ryugu and Touchdown Safety. Space Science Reviews, 216(7), [116]. https://doi.org/10.1007/s11214-020-00737-z

Kikuchi, S, Watanabe, SI, Saiki, T, Yabuta, H, Sugita, S, Morota, T, Hirata, N, Hirata, N, Michikami, T, Honda, C, Yokota, Y, Honda, R, Sakatani, N, Okada, T, Shimaki, Y, Matsumoto, K, Noguchi, R, Takei, Y, Terui, F, Ogawa, N, Yoshikawa, K, Ono, G, Mimasu, Y, Sawada, H, Ikeda, H, Hirose, C, Takahashi, T, Fujii, A, Yamaguchi, T, Ishihara, Y, Nakamura, T, Kitazato, K, Wada, K, Tachibana, S, Tatsumi, E, Matsuoka, M, Senshu, H, Kameda, S, Kouyama, T, Yamada, M, Shirai, K, Cho, Y, Ogawa, K, Yamamoto, Y, Miura, A, Iwata, T, Namiki, N, Hayakawa, M, Abe, M, Tanaka, S, Yoshikawa, M, Nakazawa, S & Tsuda, Y 2020, 'Hayabusa2 Landing Site Selection: Surface Topography of Ryugu and Touchdown Safety', Space Science Reviews, vol. 216, no. 7, 116. https://doi.org/10.1007/s11214-020-00737-z

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title = "Hayabusa2 Landing Site Selection: Surface Topography of Ryugu and Touchdown Safety",

abstract = "One of the primary goals of Hayabusa2 is to land on the asteroid Ryugu to collect its surface materials. The key for a successful touchdown is to find a promising landing site that meets both scientific and engineering requirements. Due to the limited availability of pre-arrival information about Ryugu, the landing site selection (LSS) must be conducted based on proximity observations over a limited length of time. In addition, Ryugu was discovered to possess an unexpectedly high abundance of boulders with an absence of wide and flat areas, further complicating the LSS. To resolve these problems, we developed a systematic and stepwise LSS process with a focus on the surface topography of Ryugu and the associated touchdown safety. The proposed LSS scheme consists of two phases: Phase-I LSS, a comprehensive survey of potential landing areas at the 100-m scale based on the global mapping of Ryugu, and Phase-II LSS, a narrowing-down process of the candidate landing sites at the 10-m scale using high-resolution images and a local terrain model. To verify the feasibility of a precision landing at the target site, we also investigated the landing dispersion via a Monte Carlo simulation, which incorporates the effect of the irregular surface gravity field. One of the major characteristics of the Hayabusa2 LSS developed in this study is the iterative feedback between LSS analyses on the ground and actual spacecraft operations near the target asteroid. Using the newly developed method, we chose a landing site with a radius of 3 m, and Hayabusa2 successfully conducted its first touchdown on February 21, 2019. This paper reports the methodology and results of the stepwise iterative LSS for the first Hayabusa2 touchdown. The touchdown operation results reconstructed from flight data are also provided, demonstrating the validity of the adopted LSS strategy.",

keywords = "Asteroid exploration, Landing site selection, Pinpoint touchdown, Spacecraft safety, Terrain map",

author = "Shota Kikuchi and Watanabe, {Sei ichiro} and Takanao Saiki and Hikaru Yabuta and Seiji Sugita and Tomokatsu Morota and Naru Hirata and Naoyuki Hirata and Tatsuhiro Michikami and Chikatoshi Honda and Yashuhiro Yokota and Rie Honda and Naoya Sakatani and Tatsuaki Okada and Yuri Shimaki and Koji Matsumoto and Rina Noguchi and Yuto Takei and Fuyuto Terui and Naoko Ogawa and Kent Yoshikawa and Go Ono and Yuya Mimasu and Hirotaka Sawada and Hitoshi Ikeda and Chikako Hirose and Tadateru Takahashi and Atsushi Fujii and Tomohiro Yamaguchi and Yoshiaki Ishihara and Tomoki Nakamura and Kohei Kitazato and Koji Wada and Shogo Tachibana and Eri Tatsumi and Moe Matsuoka and Hiroki Senshu and Shingo Kameda and Toru Kouyama and Manabu Yamada and Kei Shirai and Yuichiro Cho and Kazunori Ogawa and Yukio Yamamoto and Akira Miura and Takahiro Iwata and Noriyuki Namiki and Masahiko Hayakawa and Masanao Abe and Satoshi Tanaka and Makoto Yoshikawa and Satoru Nakazawa and Yuichi Tsuda",

note = "Funding Information: This work was supported by KAKENHI from the Japan Society for the Promotion of Science (JSPS) (grants JP19K21075, JP17H06459, JP19H01951, and JP19K14778), the Astrobiology Center Program of National Institutes of Natural Sciences (NINS) (grant AB311012), and the JSPS Core-to-Core program “International Network of Planetary Sciences.” Publisher Copyright: {\textcopyright} 2020, Springer Nature B.V.",

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doi = "10.1007/s11214-020-00737-z",

language = "English",

volume = "216",

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T1 - Hayabusa2 Landing Site Selection

T2 - Surface Topography of Ryugu and Touchdown Safety

AU - Kikuchi, Shota

AU - Watanabe, Sei ichiro

AU - Saiki, Takanao

AU - Yabuta, Hikaru

AU - Sugita, Seiji

AU - Morota, Tomokatsu

AU - Hirata, Naru

AU - Hirata, Naoyuki

AU - Michikami, Tatsuhiro

AU - Honda, Chikatoshi

AU - Yokota, Yashuhiro

AU - Honda, Rie

AU - Sakatani, Naoya

AU - Okada, Tatsuaki

AU - Shimaki, Yuri

AU - Matsumoto, Koji

AU - Noguchi, Rina

AU - Takei, Yuto

AU - Terui, Fuyuto

AU - Ogawa, Naoko

AU - Yoshikawa, Kent

AU - Ono, Go

AU - Mimasu, Yuya

AU - Sawada, Hirotaka

AU - Ikeda, Hitoshi

AU - Hirose, Chikako

AU - Takahashi, Tadateru

AU - Fujii, Atsushi

AU - Yamaguchi, Tomohiro

AU - Ishihara, Yoshiaki

AU - Nakamura, Tomoki

AU - Kitazato, Kohei

AU - Wada, Koji

AU - Tachibana, Shogo

AU - Tatsumi, Eri

AU - Matsuoka, Moe

AU - Senshu, Hiroki

AU - Kameda, Shingo

AU - Kouyama, Toru

AU - Yamada, Manabu

AU - Shirai, Kei

AU - Cho, Yuichiro

AU - Ogawa, Kazunori

AU - Yamamoto, Yukio

AU - Miura, Akira

AU - Iwata, Takahiro

AU - Namiki, Noriyuki

AU - Hayakawa, Masahiko

AU - Abe, Masanao

AU - Tanaka, Satoshi

AU - Yoshikawa, Makoto

AU - Nakazawa, Satoru

AU - Tsuda, Yuichi

N1 - Funding Information: This work was supported by KAKENHI from the Japan Society for the Promotion of Science (JSPS) (grants JP19K21075, JP17H06459, JP19H01951, and JP19K14778), the Astrobiology Center Program of National Institutes of Natural Sciences (NINS) (grant AB311012), and the JSPS Core-to-Core program “International Network of Planetary Sciences.” Publisher Copyright: © 2020, Springer Nature B.V.

PY - 2020/10/1

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N2 - One of the primary goals of Hayabusa2 is to land on the asteroid Ryugu to collect its surface materials. The key for a successful touchdown is to find a promising landing site that meets both scientific and engineering requirements. Due to the limited availability of pre-arrival information about Ryugu, the landing site selection (LSS) must be conducted based on proximity observations over a limited length of time. In addition, Ryugu was discovered to possess an unexpectedly high abundance of boulders with an absence of wide and flat areas, further complicating the LSS. To resolve these problems, we developed a systematic and stepwise LSS process with a focus on the surface topography of Ryugu and the associated touchdown safety. The proposed LSS scheme consists of two phases: Phase-I LSS, a comprehensive survey of potential landing areas at the 100-m scale based on the global mapping of Ryugu, and Phase-II LSS, a narrowing-down process of the candidate landing sites at the 10-m scale using high-resolution images and a local terrain model. To verify the feasibility of a precision landing at the target site, we also investigated the landing dispersion via a Monte Carlo simulation, which incorporates the effect of the irregular surface gravity field. One of the major characteristics of the Hayabusa2 LSS developed in this study is the iterative feedback between LSS analyses on the ground and actual spacecraft operations near the target asteroid. Using the newly developed method, we chose a landing site with a radius of 3 m, and Hayabusa2 successfully conducted its first touchdown on February 21, 2019. This paper reports the methodology and results of the stepwise iterative LSS for the first Hayabusa2 touchdown. The touchdown operation results reconstructed from flight data are also provided, demonstrating the validity of the adopted LSS strategy.

AB - One of the primary goals of Hayabusa2 is to land on the asteroid Ryugu to collect its surface materials. The key for a successful touchdown is to find a promising landing site that meets both scientific and engineering requirements. Due to the limited availability of pre-arrival information about Ryugu, the landing site selection (LSS) must be conducted based on proximity observations over a limited length of time. In addition, Ryugu was discovered to possess an unexpectedly high abundance of boulders with an absence of wide and flat areas, further complicating the LSS. To resolve these problems, we developed a systematic and stepwise LSS process with a focus on the surface topography of Ryugu and the associated touchdown safety. The proposed LSS scheme consists of two phases: Phase-I LSS, a comprehensive survey of potential landing areas at the 100-m scale based on the global mapping of Ryugu, and Phase-II LSS, a narrowing-down process of the candidate landing sites at the 10-m scale using high-resolution images and a local terrain model. To verify the feasibility of a precision landing at the target site, we also investigated the landing dispersion via a Monte Carlo simulation, which incorporates the effect of the irregular surface gravity field. One of the major characteristics of the Hayabusa2 LSS developed in this study is the iterative feedback between LSS analyses on the ground and actual spacecraft operations near the target asteroid. Using the newly developed method, we chose a landing site with a radius of 3 m, and Hayabusa2 successfully conducted its first touchdown on February 21, 2019. This paper reports the methodology and results of the stepwise iterative LSS for the first Hayabusa2 touchdown. The touchdown operation results reconstructed from flight data are also provided, demonstrating the validity of the adopted LSS strategy.

KW - Asteroid exploration

KW - Landing site selection

KW - Pinpoint touchdown

KW - Spacecraft safety

KW - Terrain map

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Hayabusa2 Landing Site Selection: Surface Topography of Ryugu and Touchdown Safety

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Keywords

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