Student Lead Nanosatellite Design/Build Projects: making a cost effective approach to Earth and Space Observational Science even more cost efficient

Details Student Lead Nanosatellite Design/Build Projects: making a cost effective approach to Earth and Space Observational Science even more cost efficient Student Lead Nanosatellite Design/Build Projects: making a cost effective approach to Earth and Space Observational Science even more cost efficient

Dec 2011

adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=2011agufmsa31a1961b&link_type=abstract

American Geophysical Union, Fall Meeting 2011, abstract #SA31A-1961

Physics

Geophysics

[0850] Education / Geoscience Education Research, [1704] History Of Geophysics / Atmospheric Sciences, [3360] Atmospheric Processes / Remote Sensing

Scientific paper

With the advancement of technologies and the miniaturization of sensors and electrical/computational components satellites are also undergoing miniaturization. With lower manufacturing cost and a decreased design/build cycle (~2 years from start to launch), compared to conventional large scale satellites, nanosatellites have become a cost effective alternative for satellite Earth and Space Observations. The University of Alberta student nanosatellite (10x10x30cm; <4kg) design/build team, AlbertaSat-1, is a participant in the Canadian Satellite Design Challenge (CSDC) implemented by the CSA and Geocentrix Ltd. in addition to 15 other Universities from across Canada. AlbertaSat-1 will be launched in early 2013, after a 2 year design/build process and environmental testing. AlbertaSat-1 will be an Earth Observation satellite monitoring GHG (CO2, H2O & CH4) concentrations over many regions of the earth with the use of a NIR spectrometer. Here we present the planning, design and future manufacturing of AlbertaSat-1 with a focus on budget and cost effective solutions. Since this is a student project, AlbertaSat-1 will incur certain benefits making them exempt from certain financial requirements and obtaining services and equipment at very low or no cost. The largest cost benefit of AlbertaSat-1 is the virtual elimination of labor costs by having a team consisting of only unpaid students. Labor costs of typical satellite missions can be a very costly component. The educational components of such projects offer more indirect benefits to effective development of this industry/discipline, nevertheless just as important, by developing skills and knowledge that can only be learned through realistic hands on design/build projects. Student lead projects and student design/build initiatives such as CSDC (among many others in the U.S. and Europe lead by NASA and ESA, respectively) will have a major impact on shaping the future of Space and Earth Observational Sciences. We will present the future implications of such student projects and initiatives for the development of research and engineering in Space and Earth Observational Sciences.

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