研究者業績
基本情報
- 所属
- 明治大学 理工学部 特任教授国立研究開発法人宇宙航空研究開発機構 宇宙科学研究所 名誉教授
- J-GLOBAL ID
- 200901071014528345
- researchmap会員ID
- 1000174751
- 外部リンク
2014年4月1日〜2017年9月30日
・JAXA宇宙科学研究所 プログラムディレクタ
2018年4月1日〜2020年3月31日
・JAXA宇宙科学研究所 研究総主幹
・JAXA宇宙探査イノベーションハブ ハブ長
・はやぶさ2プロジェクト スポークスパーソン
2020年4月1日〜2023年5月31日
・JAXA統括チーフエンジニア
2024年4月より,明治大学理工学部特任教授
宇宙航空研究開発機構名誉教授(2025年4月1日)
日本ロボット学会フェロー(2022年9月7日)
宇宙探査ロボットの研究開発と実用化への取り組みならびに学会運営への貢献
研究キーワード
9研究分野
5経歴
4-
2024年4月 - 現在
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2003年10月 - 2024年3月
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1993年4月 - 2003年9月
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1991年4月 - 1993年3月
委員歴
6-
2022年10月 - 現在
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2021年9月 - 現在
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2003年4月 - 2025年3月
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2020年4月 - 2022年9月
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2017年4月 - 2019年3月
受賞
12論文
133-
Journal of Evolving Space Activities Vol.1(Article ID:6) 2023年1月 査読有り最終著者
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ROBOMECH Journal 9(1) 2022年1月 査読有り最終著者責任著者<title>Abstract</title>In this paper, a novel terrain traversability prediction method is proposed for new operation environments. When an off-road vehicle is operated on rough terrains or slopes made up of unconsolidated materials, it is crucial to accurately predict terrain traversability to ensure efficient operations and avoid critical mobility risks. However, the prediction of traversability in new environments is challenging, especially for possibly risky terrains, because the traverse data available for such terrains is either limited or non-existent. To address this limitation, this study proposes an adaptive terrain traversability prediction method based on multi-source transfer Gaussian process regression. The proposed method utilizes the limited data available on low-risk terrains of the target environment to enhance the prediction accuracy on untraversed, possibly higher-risk terrains by leveraging past traverse experiences on multiple types of terrain surface. The effectiveness of the proposed method is demonstrated in scenarios where vehicle slippage and power consumption are predicted using a dataset of various terrain surfaces and geometries. In addition to predicting terrain traversability as continuous values, the utility of the proposed method is demonstrated in binary risk level classification of yet to be traversed steep terrains from limited data on safer terrains.
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ROBOMECH Journal 9(1) 2022年1月 査読有り最終著者責任著者<title>Abstract</title>Hopping robots, called hoppers, are expected to move on rough terrains, such as disaster areas or planetary environments. The uncertainties of the hopping locomotion in such environments are high, making path planning algorithms essential to traverse these uncertain environments. Planetary surface exploration requires to generate a path which minimises the risk of failure and maximises the information around the hopper. This paper newly proposes a hopping path planning algorithm for rough terrains locomotion. The proposed algorithm takes into account the motion uncertainties using Markov decision processes (MDPs), and generates paths corresponding to the terrain conditions, or the mission requirements, or both. The simulation results show the effectiveness of the proposed route planning scheme in three cases as the rough terrain, sandy and hard ground environment, and non-smooth borders.
MISC
65書籍等出版物
9-
Wiley-VCH 2009年9月 (ISBN: 9783527408528)
講演・口頭発表等
162-
The 18th International Conference on Intelligent Unmanned Systems 2022年8月11日
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The 18th International Conference on Intelligent Unmanned Systems 2022年8月11日
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72nd IAC 2021年10月27日
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IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS) 2021年9月28日
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Asia Oceania Geosciences Society 15th Annual Meeting (AOGS2021) 2021年8月3日
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IEEE/ASME International Conference on Advanced Intelligent Mechatronics(AIM) 2021年 IEEE
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International Symposium on Artificial Intelligence, Robotics and Automation in Space 2020年10月20日 招待有り
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IEEE International Conference on Robotics and Automation (ICRA) 2020年6月2日 招待有り
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IEEE/SICE International Symposium on System Integration 2020年1月13日 招待有り
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IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS) 2019年11月6日 招待有り
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2017 IEEE Aerospace Conference 2017年3月 IEEE
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The Abstracts of the international conference on advanced mechatronics : toward evolutionary fusion of IT and mechatronics : ICAM 2015年 一般社団法人 日本機械学会We have been developing a lunar subsurface excavation robot using peristaltic crawling based on an earthworm's locomotion. In existing robots, the excavated soil must be manually removed by humans. To overcome this limitation, we have been developing a mechanism that automatically removes the excavated soil. This paper presents our new automatic soil-release mechanism and demonstrates the performance of the mechanism using a prototype.
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「運動と振動の制御」シンポジウム講演論文集 2014年 一般社団法人 日本機械学会Lunar or planetary exploration is scientifically meaningful because they can give us the hint to throw a light on the origin and evolution of the solar system or the earth, the inner structure of planets, etc. In lunar or planetary exploration missions, it is important to save the weight of spacecraft. Light weight spacecraft leads to low cost and getting more chance to go to the space. Conventionally a lander carries a rover to the surface of the celestial body and the rover traverses the rough terrain to explore in wide region. If the lander and the rover are united, however, the total weight of the spacecraft could be reduced. The authors have already proposed a novel pulley suspension mechanism, which is called Load Equalization Pulley Suspension mechanism: LEPS mechanism, for rovers. The performance of the proposed mechanism as a suspension mechanism of rovers has been evaluated. In this paper, the application of LEPS mechanism to the landing gears of the lander is discussed. By applying the proposed mechanism to the landing gears, the lander can move around the wide region of the surface after landing. The landing dynamics model of the proposed "Movable lander" with LEPS mechanism is introduced. The landing performance is evaluated by 2-dimensional model. The simulation results show that LEPS mechanism has an advantage over normal landing gears.
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ロボティクス・メカトロニクス講演会講演概要集 2014年 一般社団法人 日本機械学会The performance of an integrated navigation system is studied through the field experiments on a four-wheeled test-bed rover, AKI, operated in a terrestrial analogue. The AKI rover employs novel mobility and navigation systems which enable challenging long-range operations in natural terrain. AKI has a vision-based localization system aided by sun sensors and an inclinometer for absolute attitude estimation. The integration with absolute direction sensors improves accuracy in absolute positioning, as well as obtaining 5x run-time improvement of visual pose estimation. The paper reports the results of field experiment conducted in Izu-Oshima island in 2013, and discusses current challenges of the system.
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ロボティクス・メカトロニクス講演会講演概要集 2014年 一般社団法人 日本機械学会JAXA is planning to launch Hayabusa 2 in December 2014. Hayabusa 2 will be equipped with an asteroid exploration rover which is developed by the consortium of universities. A goal of the rover is establishment of the technology for locomotion on asteroid surface. In our previous work, we proposed a new moving mechanism called "Environment-Driven Torquer, EDT." The EDT is driven by environment temperature with bimetal. In other words, the EDT can move the rover without both battery and CPU. We have developed an engineering model with magnet latch. In this paper, performance evaluation of the EDT is executed by free-fall experiments in ZARM.
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ロボティクス・メカトロニクス講演会講演概要集 2014年 一般社団法人 日本機械学会Asteroid probe Hayabusa 2 is developed by JAXA. Asteroid exploration rovers will be carried by Hayabusa 2. In our research project, we have developed an environmental-temperature-driven buckling actuator with a bimetal thin plate for a hopping mechanism of the rover. In this study, to characterize the hopping capability of the actuator, we conducted microgravity examination in ZARM drop tower. We fabricate a test rover for the microgravity examination with a rapid heating system for actuation in short free-fall time. Although reaction force from baseplate was incomplete in take-off, the rover hopped with a vertical velocity of 3.12 mm/s with 0.035 rad/s rotating rate.
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2014 IEEE 23RD INTERNATIONAL SYMPOSIUM ON INDUSTRIAL ELECTRONICS (ISIE) 2014年 IEEERecently, personal vehicles have received a lot of attention to expand our mobility for low carbon society and diversification of individual mobility. So far several small vehicles have been developed. However a new thesis of designing and controlling personal vehicles is required, because there are some difference between general vehicle-used environment and personal vehicle-used environment like mixed traffic. In such new kinds of environment, vehicles should have close relationship with drivers. To have closer relationship, personal vehicles must be smaller and lighter. In addition, designing personal vehicle's motion by considering driver's psychological evaluation, we can provide more comfortable vehicle's interface. The author defined these kinds of personal vehicle as Affinitive Personal Vehicle and focused on driver's sense of balance to estimate driver's psychological evaluation. In this paper, author shows that change of vehicle's motion effects on driver's sense of balance, and there is relation between driver's sense of balance and Kaisei evaluation.
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MOVIC 2014 - 12th International Conference on Motion and Vibration Control 2014年
担当経験のある科目(授業)
3-
制御システム理論 (東京大学大学院)
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宇宙電気電子工学 (東京大学大学院)
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宇宙探査ロボティクス (東京大学大学院)
所属学協会
4Works(作品等)
1共同研究・競争的資金等の研究課題
10-
日本学術振興会 科学研究費助成事業 2023年4月 - 2026年3月
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科学研究費補助金(基盤研究B) 2012年4月 - 2015年3月
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科学研究費補助金(基盤研究C) 2003年4月 - 2006年3月
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宇宙環境利用に関する地上公募研究(萌芽研究) 2002年4月 - 2003年3月
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科学研究費補助金(基盤研究A) 1998年4月 - 2001年3月
