Lunar Volatiles and Mineralogy Mapper (LVMM) payload for the lunar Volatile and Mineralogy Mapping Orbiter (VMMO)

Roman Kruzelecky; Piotr Murzionak; Qi-Yang Peng; Ian Sinclair; Michel Corriveau; Edward Cloutis; Alexis Parkinson; Brynn Dagdick; Amélie St-Amour; Yang Gao; Chris Bridges; Nicola Baresi; Andrea Lucca Fabris; Samantha Rowe; Nuno Silva; Paulo Rosa; Mauro Gameiro; Roger Walker; Johan Vennekens

doi:10.1117/12.2633144

30 September 2022 Lunar Volatiles and Mineralogy Mapper (LVMM) payload for the lunar Volatile and Mineralogy Mapping Orbiter (VMMO)

Roman Kruzelecky, Piotr Murzionak, Qi-Yang Peng, Ian Sinclair, Michel Corriveau, Edward Cloutis, Alexis Parkinson, Brynn Dagdick, Amélie St-Amour, Yang Gao, Chris Bridges, Nicola Baresi, Andrea Lucca Fabris, Samantha Rowe, Nuno Silva, Paulo Rosa, Mauro Gameiro, Roger Walker, Johan Vennekens

Author Affiliations +

Proceedings Volume 12236, CubeSats and SmallSats for Remote Sensing VI; 122360A (2022) https://doi.org/10.1117/12.2633144
Event: SPIE Optical Engineering + Applications, 2022, San Diego, California, United States

Abstract

The Lunar Volatile and Mineralogy Mapping Orbiter (VMMO) comprises a low-cost 12U Cubesat with deployable solar arrays, X-Band/UHF communications, option of electric or chemical propulsion, the Lunar Volatiles and Mineralogy Mapper (LVMM) payload, and an optional GPS receiver technology demonstrator. LVMM facilitates three operational modes: Active mode using illumination of the lunar surface at 532nm, 1064nm, and 1560nm to enable volatiles mapping during the lunar night and within Permanently-Shadowed Regions (PSRs); Passive mode during the lunar day with spectral channels at 300nm, 532nm, 690nm, 1064nm, and 1560nm for mapping lunar surficial ilmenite (FeTiO3); and a Communications mode for an optical data downlink demonstration at 1560nm. Previous lunar missions have detected the presence of water-ice in the lunar South Pole region. However, there is considerable uncertainty with regards to its distribution within and across the lunar surface. A number of planned future missions will further map water ice deposits, but the spatial resolution of these observations is expected to be on the order of kilometres. The LVMM using single-mode fiber lasers can improve the special resolution of the mapping to 10s of metres. VMMO has completed the Phase A study with ESA. This paper discusses the baseline LVMM payload design and its dual-use applications for both the stand-off mapping of lunar volatiles and a high-speed optical data link demonstration. In particular, the supporting fiber-laser technology readiness was advanced through ground qualification.

Conference Presentation

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Roman Kruzelecky, Piotr Murzionak, Qi-Yang Peng, Ian Sinclair, Michel Corriveau, Edward Cloutis, Alexis Parkinson, Brynn Dagdick, Amélie St-Amour, Yang Gao, Chris Bridges, Nicola Baresi, Andrea Lucca Fabris, Samantha Rowe, Nuno Silva, Paulo Rosa, Mauro Gameiro, Roger Walker, and Johan Vennekens "Lunar Volatiles and Mineralogy Mapper (LVMM) payload for the lunar Volatile and Mineralogy Mapping Orbiter (VMMO)", Proc. SPIE 12236, CubeSats and SmallSats for Remote Sensing VI, 122360A (30 September 2022); https://doi.org/10.1117/12.2633144

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