日本地球惑星科学連合2021年大会

講演情報

[E] ポスター発表

セッション記号 P (宇宙惑星科学) » P-PS 惑星科学

[P-PS04] 太陽系小天体:はやぶさ2等の宇宙ミッションからの新展開

2021年6月6日(日) 17:15 〜 18:30 Ch.04

コンビーナ:岡田 達明(宇宙航空研究開発機構宇宙科学研究所)、中本 泰史(東京工業大学)、黒田 大介(京都大学)

17:15 〜 18:30

[PPS04-P25] Development status of DESTINY+ onboard cameras TCAP and MCAP

*石橋 高1、洪 鵬1、岡本 尚也2、石丸 貴博2、山田 学1、尾崎 直哉2、細沼 貴之3、佐藤 峻介2、奥平 修1、荒井 朋子1、吉田 二美1,4、鍵谷 将人5、亀田 真吾6、宮原 剛2、太田 方之2、高島 健2 (1.千葉工業大学、2.宇宙航空研究開発機構、3.東京大学、4.産業医科大学、5.東北大学、6.立教大学)

キーワード:デスティニープラス、(3200)ファエトン、カメラ、フライバイ撮像

DESTINY+ (Demonstration and Experiment of Space Technology for INterplanetary voYage with Phaethon fLy-by and dUst Science) is a mission proposed for JAXA/ISAS Epsilon class small program, scheduled to be launched in 2024 [1]. The flyby target of the DESTINY+ mission is the near-Earth asteroid (3200) Phaethon, which is known as an active asteroid and a parent body of the Geminid meteor shower. The size of (3200) Phaethon is 5 to 6 km in diameter. The spacecraft will flyby (3200) Phaethon with a distance of 500±50 km at the closest approach and relative speeds of ~35 km/s. In this mission, spatially resolved images of (3200) Phaethon will be taken by two onboard cameras, the Telescopic CAmera for Phaethon (TCAP) and the Multiband CAmera for Phaethon (MCAP). These observations would help understand the nature of a meteor shower's parent body, one of the sources of interplanetary dust particles that are thought to be an important transport medium of organic matter to the Earth.

TCAP is a panchromatic camera that observes the global shape, the semi-global features, and local surface features of (3200) Phaethon. To achieve those observations TCAP has a tracking mirror that can change the boresight of TCAP and can keep (3200) Phaethon in the field of view (FOV) of TCAP all the time during the flyby. The focal length, aperture, FOV, and IFOV (FOV per pixel) of TCAP are 790 mm, φ114 mm, 0.82 deg × 0.82 deg, and 7.0 μrad/pixel, respectively. TCAP also plays the role of the optical navigation camera for the flyby observation. The specifications above are required for both the scientific imaging and for achieving the flyby imaging sequence.

MCAP is a multiband camera, the wavelengths of which are 425, 550, 700, 850 nm. The focal length, aperture, FOV, and IFOV are 100 mm, φ21 mm, 6.5 deg × 6.5 deg, and 55 μrad/pixel, respectively, for all the bands. MCAP has multiple optical systems and sensors to take all band images simultaneously. We are considering a branching optical system for MCAP, which separates incident light into two imaging sensors using a dichroic prism. Thus, four bands can be covered with two branching optical systems. MCAP does not have a tracking mirror because of a strict weight limitation and will take images at the solar phase angles of around 10 deg, where the amount of the reflected light is enough to achieve high signal-to-noise ratios.

The observation for searching (3200) Phaethon will start 30 days before the encounter. We estimated the time of detection of (3200) Phaethon using the phase curve of (3200) Phaethon obtained by ground observation, and (3200) Phaethon will be detected by TCAP at least ten days before or earlier the encounter. The optical navigation using TCAP images to estimate relative trajectory will be conducted 5 to 2.5 days before the encounter. Then, the images of (3200) Phaethon will be taken around the closest approach for scientific objectives. Since the angular velocity at the closest approach is around 4 deg/s, which is too high to track by spacecraft attitude control only, the tracking mirror is required.

High pointing accuracy and pointing stability are required to keep the asteroid in the FOV of TCAP and image the asteroid without motion blur. We set the pointing accuracy requirement to ≦0.05 deg (1σ) and ≦0.067 deg (1σ) for the horizontal and vertical directions, respectively. The pointing stability requirement during 0.3 msec, the nominal exposure time of TCAP, is set to ≦4×10-4 deg/0.3 msec (1σ), which corresponds to 1 pixel. The main error sources in TCAP include the tracking mirror motion [2] and the alignment among the telescope's boresight, the rotational axis of the tracking mirror, and the direction of the mirror. We have been evaluating those errors, and the preliminary results show that the requirements are satisfied.

References: [1] Arai, T. et al. (2020) LPS LII, Abstract #1896. [2] Hong, P. et al. (2020) LPS LII, Abstract #1741.