Your search keyword '"Caudill, Christy"' showing total 2 results

1. CanMars mission Science Team operational results: Implications for operations and the sample selection process for Mars Sample Return (MSR).

Author

Caudill, Christy M., Pontefract, Alexandra J., Osinski, Gordon R., Tornabene, Livio L., Pilles, Eric A., Battler, Melissa, Francis, Raymond, Godin, Etienne, Grau Galofre, Anna, Haltigin, Timothy, Hipkin, Victoria J., Mittelholz, Anna, Poitras, Jordan, Simpson, Sarah L., Svensson, Matthew, Xie, Tianqi, and Morse, Zachary R.

Subjects

*SAMPLING (Process), *MARS (Planet), *DRILLING & boring, *LABORATORIES, *OPERATIONS management, *WORKFLOW management, *TEAMS

Abstract

The CanMars Mars sample return (MSR) analogue mission was conducted as a field and operational test for the Mars 2020 sample cache rover mission and was the most realistic known MSR rover analogue mission to-date. A rover — similar in scale to that of rover planned for NASA's Mars 2020 mission — was deployed to a scientifically relevant Mars-analogue sedimentary field site with remote mission operations conducted at the University of Western Ontario, Canada; the mission aim was to inform on best practices and optimal approaches for sample acquisition modeled on the Mars 2020 rover mission. The daily operational procedures of the CanMars Science Team were modeled on those of current missions (i.e., Mars Science Laboratory tactical operations), serving as a study of known operational workflows and as a testbed for new approaches. This paper reports on the operational results of CanMars with best-practice recommendations. CanMars was designed as a Mars 2020 mock mission and thus carried similar science objectives; these included (1) advancing the understanding of the habitability potential of a subaqueous sedimentary environment through identifying, characterizing, and caching drilled samples containing high organic carbon (as a proxy for preserved ancient biosignatures) and (2) advancing the understanding of the history of water at the site. The in situ science investigations needed to address these science objectives were guided by the Mars Exploration Program Analysis Group goals. Effective and efficient Science Team operational procedures were developed – and many lessons were documented – through daily tactical planning and science investigations employed to meet the sample acquisition goals. In addition to the documentation of the CanMars operational procedures, this paper provides a brief summary of the science results from CanMars with a focus on recommendations for future analogue missions and planetary sample return flight missions, providing specific value to operational procedures for the Mars 2020 rover mission. • Rover mission operations management, procedures, and workflows were vetted. • We document the complex Science Team interactions relevant to operational workflows. • An intentional operational structure must be employed for optimal use of very limited mission time. [ABSTRACT FROM AUTHOR]

Published

2019

2. Field and laboratory validation of remote rover operations Science Team findings: The CanMars Mars Sample Return analogue mission.

Author

Caudill, Christy M., Osinski, Gordon R., Pilles, Eric, Sapers, Haley M., Pontefract, Alexandra J., Francis, Raymond, Duff, Shamus, Laughton, Joshua, O'Callaghan, Jonathan, Sopoco, Racel, Tolometti, Gavin, Tuite, Michael, Williford, Kenneth H., and Xie, Tianqi

Subjects

*MARS (Planet), *LABORATORIES, *BASEBALL fields, *TEAMS in the workplace, *ACQUISITION of data, *TEAMS, *SPECTROMETERS

Abstract

The CanMars Mars Sample Return Analogue Deployment (MSRAD) was a closely simulated, end-to-end Mars Sample Return (MSR) mission scenario, with instrumentation, goals, and constraints modeled on the upcoming NASA Mars 2020 rover mission; this paper reports on the post-mission validation of the exercise. The exercise utilized the CSA Mars Exploration Science Rover (MESR) rover, deployed to Utah, USA, at a Mars-analogue field site. The principal features of the field site located near Green River, Utah are Late Jurassic inverted, fluvial paleochannels, analogous to features on Mars in sites being considered for the ESA ExoMars rover mission and present within the chosen landing site for the Mars 2020 rover mission. The in-simulation ("in-sim") mission operations team worked remotely from The University of Western Ontario, Canada. A suite of MESR-integrated and hand-held spectrometers was selected to mimic those of the Mars 2020 payload, and a Utah-based, on-site team was tasked with field operations to carry out the data collection and sampling as commanded by the in-sim team. As a validation of the in-sim mission science findings, the field team performed an independent geological assessment. This paper documents the field team's on-site geological assessment and subsequent laboratory and analytical results, then offers a comparison of mission (in-sim) and post-mission (laboratory) science results. The laboratory-based findings were largely consistent with the in-sim rover-derived data and geological interpretations, though some notable exceptions highlight the inherent difficulties in remote science. In some cases, available data was insufficient for lithologic identification given the absence of other important contextual information (e.g., textural information). This study suggests that the in-sim instruments were largely adequate for the Science Team to characterize samples; however, rover-based field work is necessarily hampered by mobility and time constraints with an obvious effect on efficiency but also precision, and to some extent, accuracy of the findings. The data show a dearth of preserved total organic carbon (TOC) – used as a proxy for ancient biosignature preservation potential – in the fluvial-lacustrine system of this field site, suggesting serious consideration with respect to the capabilities and opportunities for addressing the Mars exploration goals. We therefore suggest a thorough characterization of terrestrial sites analogous to those of Mars rover landing sites, and in-depth field studies like CanMars as important, pre-mission strategic exercises. • We present a field geological assessment of the CanMars analogue mission field site. • Characterization of terrestrial, analogous Mars landing sites is crucial for mission success. • In-depth field studies allow an understanding of how to address habitability potential. [ABSTRACT FROM AUTHOR]

Published

2019