The MVACS Surface Stereo Imager on Mars Polar Lander

Smith, Peter H.; Reynolds, R.; Weinberg, J.; Friedman, Terry; Lemmon, M. T.; Tanner, R.; Reid, Robert J.; Marcialis, R. L.; Bos, Brent J.; Oquest, C.; Keller, H. U.; Markiewicz, W. J.; Kramm, R.; Gliem, F.; Rueffer, P.

doi:10.1029/1999je001116

Cited by 15 publications

(25 citation statements)

References 35 publications

(27 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The RA is also outfitted with the Robotic Arm Camera (RAC) to monitor the trench site(s) and samples within the scoop with high‐resolution, full‐color images [ Bonitz et al , 2001] and a Thermal and Electrical Conductivity Probe (TECP) [ Zent et al , 2008] to determine soil and ice properties and to measure atmospheric relative humidity. At the same time, the Surface Stereo Imager (SSI) will acquire stereo views of the landing site, surrounding terrain, and trenching operations [ Smith et al , 2001]. The SSI resides on a mast roughly 2 m above the ground surface and contains 13 visible and near‐infrared narrow band pass filters to identify geologically interesting materials.…”

Section: Introductionmentioning

confidence: 99%

Geomorphologic and mineralogic characterization of the northern plains of Mars at the Phoenix Mission candidate landing sites

Seelos

Arvidson²,

Cull³

et al. 2008

J. Geophys. Res.

View full text Add to dashboard Cite

[1] A suite of remote sensing data is used to evaluate both geomorphology and mineralogy of the candidate landing sites for the 2007 Phoenix Mission. Three candidate landing site boxes are situated in the northern plains of Mars on the distal flank of Alba Patera in the region from 67°N to 72°N and from $230°E to 260°E. Geomorphology is mapped at subkilometer spatial scales using Thermal Emission Imaging System (THEMIS) visible and Mars Orbiter Laser Altimeter (MOLA) topographic data, supplemented by images from the High-Resolution Imaging Science Experiment (HiRISE) and Context Imager (CTX). Mineralogy and spectral properties are examined using Compact Reconnaissance Imaging Spectrometer for Mars (CRISM) visible and near-infrared multispectral mapping and targeted hyperspectral data at $200 and $20 m/pixel, respectively. Geomorphic mapping supports the idea that terrains along the boundary between the Amazonian Scandia region and Vastitas Borealis marginal geologic units have undergone extensive modification. Intercrater plains are disrupted to form mesas and interlocking blocks, while irregular depressions and knobby terrain are consistent with erosion/subsidence and local deposition. Despite the varied morphology, the present-day surface is nearly homogeneous with spectral signatures dominated by nanophase iron oxides and basaltic sand and rocks, similar to that of the Gusev crater plains at the Mars Exploration Rover (MER) landing site. The compilation of geomorphic and spectral information for the candidate Phoenix landing sites provides a framework for the mission's in situ observations to be extrapolated to the northern plains as a whole.

show abstract

Section: Introductionmentioning

confidence: 99%

Geomorphologic and mineralogic characterization of the northern plains of Mars at the Phoenix Mission candidate landing sites

Seelos

Arvidson²,

Cull³

et al. 2008

J. Geophys. Res.

View full text Add to dashboard Cite

show abstract

“…H . Smith et al , ]. Communication with MPL was not reestablished following the landing sequence, and the craft was declared lost.…”

Section: Mars Surface Cameras 1971–2012mentioning

confidence: 99%

“…H . Smith et al , ]. However, rather than the single CCD shared between both eyes as with the IMP and Mars Polar Lander SSI, the Phoenix SSI used two 1024 pixel square CCDs, the same sensors (flight spares) as the MER Pancams [ Moores et al , ].…”

Section: Mars Surface Cameras 1971–2012mentioning

confidence: 99%

Mars surface context cameras past, present, and future

Gunn

Cousins

2016

Earth and Space Science

View full text Add to dashboard Cite

Mars has been the focus of robotic space exploration since the 1960s, in which time there have been over 40 missions, some successful, some not. Camera systems have been a core component of all instrument payloads sent to the Martian surface, harnessing some combination of monochrome, color, multispectral, and stereo imagery. Together, these data sets provide the geological context to a mission, which over the decades has included the characterization and spatial mapping of geological units and associated stratigraphy, charting active surface processes such as dust devils and water ice sublimation, and imaging the robotic manipulation of samples via scoops (Viking), drills (Mars Science Laboratory (MSL) Curiosity), and grinders (Mars Exploration Rovers). Through the decades, science context imaging has remained an integral part of increasingly advanced analytical payloads, with continual advances in spatial and spectral resolution, radiometric and geometric calibration, and image analysis techniques. Mars context camera design has encompassed major technological shifts, from single photomultiplier tube detectors to megapixel charged-couple devices, and from multichannel to Bayer filter color imaging. Here we review the technological capability and evolution of science context imaging instrumentation resulting from successful surface missions to Mars, and those currently in development for planned future missions.

show abstract

“…With two “eyes” it has the capability of providing a digital elevation model of the local surface and any modifications made to the surface. The design of the SSI is based on the Imager for Mars Pathfinder (IMP [ Smith et al ,1997]) and the MPL SSI [ Smith et al , 2001], but it has been enhanced to four times the resolving power by using the MER CCD detector package. Each “eye” has a one megapixel capacity and the ability to create a complete panorama using a subset of 13 geological filters that span the spectral range from 440 to 1000 nm.…”

Section: Measurements To Meet the Objectivesmentioning

confidence: 99%

Introduction to special section on the Phoenix Mission: Landing Site Characterization Experiments, Mission Overviews, and Expected Science

et al. 2008

Self Cite

View full text Add to dashboard Cite

Phoenix, the first Mars Scout mission, capitalizes on the large NASA investments in the Mars Polar Lander and the Mars Surveyor 2001 missions. On 4 August 2007, Phoenix was launched to Mars from Cape Canaveral, Florida, on a Delta 2 launch vehicle. The heritage derived from the canceled 2001 lander with a science payload inherited from MPL and 2001 instruments gives significant advantages. To manage, build, and test the spacecraft and its instruments, a partnership has been forged between the Jet Propulsion Laboratory, the University of Arizona (home institution of principal investigator P. H. Smith), and Lockheed Martin in Denver; instrument and scientific contributions from Canada and Europe have augmented the mission. The science mission focuses on providing the ground truth for the 2002 Odyssey discovery of massive ice deposits hidden under surface soils in the circumpolar regions. The science objectives, the instrument suite, and the measurements needed to meet the objectives are briefly described here with reference made to more complete instrument papers included in this special section. The choice of a landing site in the vicinity of 68°N and 233°E balances scientific value and landing safety. Phoenix will land on 25 May 2008 during a complex entry, descent, and landing sequence using pulsed thrusters as the final braking strategy. After a safe landing, twin fan‐like solar panels are unfurled and provide the energy needed for the mission. Throughout the 90‐sol primary mission, activities are planned on a tactical basis by the science team; their requests are passed to an uplink team of sequencing engineers for translation to spacecraft commands. Commands are transmitted each Martian morning through the Deep Space Network by way of a Mars orbiter to the spacecraft. Data are returned at the end of the Martian day by the same path. Satisfying the mission's goals requires digging and providing samples of interesting layers to three on‐deck instruments. By verifying that massive water ice is found near the surface and determining the history of the icy soil by studying the mineralogical, chemical, and microscopic properties of the soil grains, Phoenix will address questions concerning the effects of climate change in the northern plains. A conclusion that unfrozen water has modified the soil naturally leads to speculation as to the biological potential of the soil, another scientific objective of the mission.

show abstract

The MVACS Surface Stereo Imager on Mars Polar Lander

Cited by 15 publications

References 35 publications

Geomorphologic and mineralogic characterization of the northern plains of Mars at the Phoenix Mission candidate landing sites

Geomorphologic and mineralogic characterization of the northern plains of Mars at the Phoenix Mission candidate landing sites

Mars surface context cameras past, present, and future

Introduction to special section on the Phoenix Mission: Landing Site Characterization Experiments, Mission Overviews, and Expected Science

Contact Info

Product

Resources

About