Feasibility study of a DNA-sequencing CubeSat satellite

Paper number

IAC-17,E2,1,11,x41892

Author

Mr. Jeremie Joannes, University of Bristol, United Kingdom

Year

2017

Abstract

Sequencing the genomes of bacteria in a space environment may reveal
insight into the origins of life on Earth. Designing a CubeSat satellite capable of cultivating and sequencing Bacillus subtilis genomes in space presents significant engineering challenges. The present study aims to assess the feasibility of such a mission, using a systems engineering approach initially focussed on the biological payload selection, then on the space segment aspects of the mission. These are analysis of potential orbits and thermal, power and communications subsystems, each deemed to be critical system
drivers. Both sun-synchronous and International Space Station orbits were found to be feasible, although aerodynamic drag limits the satellite lifetime to a year in the latter. Power analysis indicated the requirement for a deployable solar array, which is atypical for CubeSats due to additional complexity.
Although communications analysis found the currently attainable data rate insufficient to download results within a reasonable timeframe, solutions to this problem are presented. A critical assessment of the methods used showed the power and communications models to be reliable. Thermal analysis predicted unfavourably high temperatures, jeopardising the survival of the biological payload, although this model was finally deemed unreliable. Although the biological payload technology requires significant development, this study found the space segment of the mission to be feasible, subject to analysis of
the proposed improvements.

Abstract document

IAC-17,E2,1,11,x41892.brief.pdf

Manuscript document

(absent)