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Abstract

One of the future flagship missions of the European Space Agency is the asteroid sample return mission Marco-Polo. Although there have been a number of past missions to asteroids, a sample has never been successfully returned. The return of asteroid regolith to the Earth's surface introduces new technical challenges. This article develops attitude control algorithms for the descent phase onto an asteroid in micro-gravity conditions and draws a comparison between the algorithms considered. Two studies are also performed regarding the fault detection isolation and recovery of the control laws considered. The potential of using direct adaptive control (DAC) as a controller for the surface sampling process is also investigated. The use of a DAC controller incorporates increased levels of robustness by allowing real-time variation of control gains. This leads to better response to uncertainties encountered during missions.

Keywords

autonomy asteroid direct adaptive control fault detection isolation and recovery

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References

Faye

Villefrache

Evans

‘Rosetta: The ESA comet rendevous mission’

Acta Astronaut. 40 (1997): 871–877

A'Hearn

M. F.

Combi

M. R.

‘Deep impact at comet Tempel 1’ (2007) ICARUS, 0019–1035.

Tatsuaki

Takashi

Masatsugu

‘Touchdown dynamics for sample collection in hayabusa mission’ In Proceedings of the 2008 IEEE International Conference on Robotics and automation, Pasadena, 19–23 May 2008.

Ichiro

Tetsua

Takashi

‘Hopping rover ‘minerva’ for asteroid exploration’. In Proceedings of the Fifth International Symposium on Artificial intelligence, 1–3 June 1999, number ESA SP 440, ESA.

Ulamec

Biele

‘Capabilities of philae, the rosetta lander’

Space Sci. Rev. 138 (2008): 275–289

Widnall

W. S.

‘Lunar module digital autopilot’

J. Spacecr. Rockets 8 (1970): 56–60

Sembely

‘Lignc summary report, EADS Astrium’ (2005): EEA.TCN.97388.ASTR.

Mukherji

Allen

Langley

‘Full-scale testing and platform stabilization of a scanning lidar system for plantery landing’. In Proceedings of the Conference on Space exploration technologies, Orlando, March 2008.

Tripp

Lafontaine

Ulitsky

‘Laps the development of a scanning lidar system with gnc for autonomous hazard avoidance and precision landing’. In Proceedings of the Conference on Spaceboard sensors, Orlando, April 2004.

10.

Della Torre

Guizzo

G. P.

Bertoli

‘Testing GNC technologies for planetary landing on mars and moon analogues’. In Proceedings of the Second International Workshop on Exploring Mars and its Earth analogues, Trento, June 2007.

11.

Della Torre

Guizzo

Bertoli

‘Mars and moon exploration passing through the European precision landing GNC test facility’. In Proceedings of the 58th International Astronautical Congress, Hyderabad, India, September 2007.

12.

Yoshikawa

Michel

Barucci

‘Marco polo: Near earth object sample return mission’

Exp. Astron. 23 (2009): 785–808

13.

Bertram

R. E.

Kalman

R. E.

‘Control system analysis and design via the second method of lyapunov, part I: Continuous systems’

ASME 83 (1960): 371–393

14.

Bertram

R. E.

Kalman

R. E.

‘Control system analysis and design via the second method of lyapunov, part II: Discrete systems’

ASME 83 (1960): 394–400

15.

Radice

Behavior based autonomy for single and multiple spacecraft (University of Glasgow 2002) PhD Thesis.

16.

Bernstein

D. S.

Hong

‘Adaptive stabilization of non-linear oscillators using direct adaptive control’

Int. J. Control 74 (2000): 432–444

17.

Bernstein

D. S.

Hong

Cummings

I. A.

‘Experimental application of direct adaptive control laws for adaptive stabilization and command following’ In Proceedings of the Conference on Decision and control, number TuM11-1440, Pheonix, December 1999.

18.

Houjun

Yimei

Zhengzhi

‘Direct adaptive control for nonlinear uncertain system based on control lyapunov function method’

J. Syst. Eng. Electron. 17 (2006): 619–623

19.

McInnes

C. R.

‘Direct adaptive control for gravity-turn descent’

J. Guid. 22 (1998): 374–377

20.

Taylor

Classical mechanics (Mill Valley, California: University Science Books 2005)

21.

Nasa guidebook for safety critical software - analysis and development. NASA Lewis Research Center, NASA-GB-8719.13, 1995.

22.

Padovan

Casotto

‘Detecting body tides and librations of europa with an altimetric exploration mission’. In Proceedings of the Astrodynamics Specialist Conference, Honolulu, August 2008, AIAA paper 2008-7200.

23.

Agnolon

‘Study overview of the near earth asteroid sample return’ (2007): ESA, SCI-PA/2007/004/PA.

Dynamic intelligent autonomous control of an asteroid lander

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