Jeffrey J. Biesiadecki scite author profile

A robotic vehicle called ATHLETE-the All-Terrain Hex-Limbed, Extra-Terrestrial Explorer-is described, along with initial results of field tests of two prototype vehicles. This vehicle concept is capable of efficient rolling mobility on moderate terrain and walking mobility on extreme terrain. Each limb has a quick-disconnect tool adapter so that it can perform general-purpose handling, assembly, maintenance, and servicing tasks using any or all of the limbs.

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Dangers of Multiple Time Step Methods

Biesiadecki

Skeel

1993

Journal of Computational Physics

123

101

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The Mars Exploration Rover Surface Mobility Flight Software: Driving Ambition

Biesiadecki

Maimone

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Cohesions, friction angles, and other physical properties of Martian regolith from Mars Exploration Rover wheel trenches and wheel scuffs

Sullivan¹,

Anderson²,

Biesiadecki³

et al. 2011

J. Geophys. Res.

100

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[1] The Mars Exploration Rovers Spirit and Opportunity investigated the physical properties of Martian regolith in 7 wheel trenches and 20 wheel scuffs distributed along traverses at Gusev crater and Meridiani Planum. Specialized wheel-trenching sequences allowed analysis of wheel motor and suspension telemetry to determine regolith friction angle and cohesion c at trench sites. Friction angles were 30°-37°, and cohesions were 0-2 kPa. Simpler wheel-scuff maneuvers were analyzed for cohesion by assuming the range of determined from trenches; cohesions in wheel-scuffed regoliths were from 0 to 11 kPa. Regolith and c can be related to regolith origins. Grain sorting, compaction, shape, size, and angularity influence . Impact cratering and aeolian processes have affected grain angularity and sorting of Martian regolith at both Mars Exploration Rover (MER) landing sites and contend in opposing ways to determine grain characteristics in the regolith. Friction angles are consistent with dry, rigid, nonplaty grains with particle size frequencies dominated by very fine sand (as seen by the Microscopic Imager or MI) with at least some grain rounding (unresolved by MI), reflecting physical weathering from aeolian saltation. Friction angle results from MER trenches therefore indicate that regolith states are between fully mature aeolian materials and impact debris. MI and color Pancam views show trench tailings and trench floors are redder, brighter, and have more intermixed extremely fine (unresolved) grains than regolith closer to the surface disturbed and exposed only by rolling tracks.Citation: Sullivan, R., R. Anderson, J. Biesiadecki, T. Bond, and H. Stewart (2011), Cohesions, friction angles, and other physical properties of Martian regolith from Mars Exploration Rover wheel trenches and wheel scuffs,

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