Title :
Mars Microprobe entry analysis
Author :
Braun, Robert D. ; Mitcheltree, Robert A. ; Cheatwood, F. McNeil
Author_Institution :
NASA Langley Res. Center, Hampton, VA, USA
Abstract :
The Mars Microprobe mission will provide the first opportunity for subsurface measurements, including water detection, near the south pole of Mars. In this paper, performance of the Microprobe aeroshell design is evaluated through development of a six-degree-of-freedom (6-DOF) aerodynamic database and flight dynamics simulation. Numerous mission uncertainties are quantified and a Monte-Carlo analysis is performed to statistically assess mission performance. Results from this 6-DOF Monte-Carlo simulation demonstrate that, in a majority of the cases (approximately 2-σ), the penetrator impact conditions are within current design tolerances. Several trajectories are identified in which the current set of impact requirements are not satisfied. From these cases, critical design parameters are highlighted and additional system requirements are suggested. In particular, a relatively large angle-of-attack range near peak heating is identified
Keywords :
Mars; Monte Carlo methods; aerodynamics; aerospace computing; aerospace simulation; planetary surfaces; space research; 6-DOF Monte-Carlo simulation; Mars Microprobe entry analysis; aeroshell design; aeroshell selection; aerosynamics; angle-of-attack range; atmospheric flight dynamics; critical design parameters; flight dynamics simulation; mission performance; mission uncertainties; peak heating; six-degree-of-freedom aerodynamic database; south pole; subsurface measurements; water detection; Aerodynamics; Instruments; Mars; NASA; Performance analysis; Postal services; Probes; Protection; Vehicle dynamics; Vehicles;
Conference_Titel :
Aerospace Conference, 1997. Proceedings., IEEE
Conference_Location :
Snowmass at Aspen, CO
Print_ISBN :
0-7803-3741-7
DOI :
10.1109/AERO.1997.574416
