Results from the Mars Phoenix Lander Robotic Arm experiment

Arvidson, R. E.; Bonitz, R.G.; Robinson, M.; Carsten, Joseph; Volpe, R.; Trebi-Ollennu, A.; Mellon, M. T.; Chu, Philip; Davis, K.; Wilson, Jim; Shaw, A.; Greenberger, R. N.; Siebach, K. L.; Stein, Thomas; Cull, Selby; Goetz, W.; Morris, R. V.; Ming, D. W.; Keller, H. U.; Lemmon, M. T.; Sizemore, H. G.; Mehta, Manish

doi:10.1029/2009je003408

Cited by 100 publications

(85 citation statements)

References 25 publications

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“…The soil component utilized optical constants based on a Mauna Kea palagonite sample: a low‐temperature alteration product of fine‐grained basaltic ash [ Clancy et al , 1995]. Based on both orbital and ground observations, dehydrated palagonite mixed with nanophase iron oxides appears to be a good analog for the Phoenix site soils [ Arvidson et al , 2009; Heet et al , 2009]. For modeling, optical constants were used from Hansen [1997, 2005] for CO 2 ice, Warren [1984] for H 2 O ice, and solid densities of ρ = 1.562 g/cm 3 for solid CO 2 , ρ = 0.9167 g/cm 3 for solid H 2 O, and ρ = 2.700 g/cm 3 for palagonite were assumed.…”

Section: Spectral Fitting: Data Sets and Methodsmentioning

confidence: 99%

“…The Phoenix primary and extended mission lasted most of the Martian northern summer (L s ∼80° to 145°) [ Smith et al , 2009; Arvidson et al , 2009]. However, our understanding of ice and dust cycles at the landing site is incomplete without analyses of ice evolution from L s ∼145° to L s ∼80° (late summer, fall, winter, and spring).…”

Section: Introductionmentioning

confidence: 99%

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Seasonal H₂O and CO₂ ice cycles at the Mars Phoenix landing site: 1. Prelanding CRISM and HiRISE observations

Cull¹,

Arvidson²,

Mellon³

et al. 2010

J. Geophys. Res.

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[1] The condensation, evolution, and sublimation of seasonal water and carbon dioxide ices were characterized at the Mars Phoenix landing site from Martian northern midsummer to midspring (L s ∼ 142°-L s ∼ 60°) for the year prior to the Phoenix landing on 25 May 2008. Ice relative abundances and grain sizes were estimated using data from the Compact Reconnaissance Imaging Spectrometer for Mars and High Resolution Imaging Science Experiment aboard Mars Reconnaissance Orbiter and a nonlinear mixing model. Water ice first appeared at the Phoenix landing site during the afternoon in late summer (L s ∼ 167°) as an optically thin layer on top of soil. CO 2 ice appeared after the fall equinox. By late winter (L s ∼ 344°), the site was covered by relatively pure CO 2 ice (∼30 cm thick), with a small amount of ∼100 mm diameter water ice and soil. As spring progressed, CO 2 ice grain sizes gradually decreased, a change interpreted to result from granulation during sublimation losses. The combined effect of CO 2 sublimation and decreasing H 2 O ice grain sizes allowed H 2 O ice to dominate spectra during the spring and significantly brightened the surface. CO 2 ice disappeared by early spring (L s ∼ 34°) and H 2 O ice by midspring (L s ∼ 59°). Spring defrosting was not uniform and occurred more rapidly over the centers of polygons and geomorphic units with relatively higher thermal inertia values.

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Section: Spectral Fitting: Data Sets and Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Seasonal H₂O and CO₂ ice cycles at the Mars Phoenix landing site: 1. Prelanding CRISM and HiRISE observations

Cull¹,

Arvidson²,

Mellon³

et al. 2010

J. Geophys. Res.

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“…2188N, 234.2508E, IAU 2000, including the 12 trenches that Phoenix excavated using its Robotic Arm (RA, Figure 1) [Arvidson et al, 2009]. With SSI, we examined soil features in each of the 12 trenches and compared them to undisturbed surface soils.…”

Section: Spectral Mappingmentioning

confidence: 99%

Concentrated perchlorate at the Mars Phoenix landing site: Evidence for thin film liquid water on Mars

Cull

Arvidson

Catalano

et al. 2010

Geophysical Research Letters

101

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NASA's Phoenix mission, which landed on the northern plains of Mars in 2008, returned evidence of the perchlorate anion distributed evenly throughout the soil column at the landing site. Here, we use spectral data from Phoenix's Surface Stereo Imager to map the distribution of perchlorate salts at the Phoenix landing site, and find that perchlorate salt has been locally concentrated into subsurface patches, similar to salt patches that result from aqueous dissolution and redistribution on Earth. We propose that thin films of liquid water are responsible for translocating perchlorate from the surface to the subsurface, and for concentrating it in patches. The thin films are interpreted to result from melting of minor ice covers related to seasonal and long‐term obliquity cycles.

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“…10) as seen by the Phoenix Mars lander. 35 The images below (Fig. 11) illustrate different steps in AGFA's processing cycle, and are automatically generated as benchmarks upon completion of the image smoothing, connected components labeling, and feature extraction steps, respectively.…”

Section: Agfa Real World Application Examplementioning

confidence: 99%

Tier-scalable reconnaissance: the future in autonomous C4ISR systems has arrived: progress towards an outdoor testbed

Fink

Brooks

Tarbell

et al. 2017

Micro- And Nanotechnology Sensors, Systems, and Applications IX

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Autonomous reconnaissance missions are called for in extreme environments, as well as in potentially hazardous (e.g., the theatre, disaster-stricken areas, etc.) or inaccessible operational areas (e.g., planetary surfaces, space). Such future missions will require increasing degrees of operational autonomy, especially when following up on transient events. Operational autonomy encompasses: (1) Automatic characterization of operational areas from different vantages (i.e., spaceborne, airborne, surface, subsurface); (2) automatic sensor deployment and data gathering; (3) automatic feature extraction including anomaly detection and region-of-interest identification; (4) automatic target prediction and prioritization; (5) and subsequent automatic (re-)deployment and navigation of robotic agents. This paper reports on progress towards several aspects of autonomous C 4 ISR systems, including: Caltech-patented and NASA award-winning multi-tiered mission paradigm, robotic platform development (air, ground, water-based), robotic behavior motifs as the building blocks for autonomous telecommanding, and autonomous decision making based on a Caltech-patented framework comprising sensor-data-fusion (feature-vectors), anomaly detection (clustering and principal component analysis), and target prioritization (hypothetical probing).

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Results from the Mars Phoenix Lander Robotic Arm experiment

Cited by 100 publications

References 25 publications

Seasonal H₂O and CO₂ ice cycles at the Mars Phoenix landing site: 1. Prelanding CRISM and HiRISE observations

Seasonal H₂O and CO₂ ice cycles at the Mars Phoenix landing site: 1. Prelanding CRISM and HiRISE observations

Concentrated perchlorate at the Mars Phoenix landing site: Evidence for thin film liquid water on Mars

Tier-scalable reconnaissance: the future in autonomous C4ISR systems has arrived: progress towards an outdoor testbed

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Results from the Mars Phoenix Lander Robotic Arm experiment

Cited by 100 publications

References 25 publications

Seasonal H2O and CO2 ice cycles at the Mars Phoenix landing site: 1. Prelanding CRISM and HiRISE observations

Seasonal H2O and CO2 ice cycles at the Mars Phoenix landing site: 1. Prelanding CRISM and HiRISE observations

Concentrated perchlorate at the Mars Phoenix landing site: Evidence for thin film liquid water on Mars

Tier-scalable reconnaissance: the future in autonomous C4ISR systems has arrived: progress towards an outdoor testbed

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Seasonal H₂O and CO₂ ice cycles at the Mars Phoenix landing site: 1. Prelanding CRISM and HiRISE observations

Seasonal H₂O and CO₂ ice cycles at the Mars Phoenix landing site: 1. Prelanding CRISM and HiRISE observations