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Auto-tuned thermal control on stratospheric balloon experiments

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arxiv 1807.09869 v1 pith:NGRPSJ2K submitted 2018-07-25 astro-ph.IM

Auto-tuned thermal control on stratospheric balloon experiments

classification astro-ph.IM
keywords thermaldesignmusttelescopeballoon-bornecontrolenvironmentgradients
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Balloon-borne telescopes present unique thermal design challenges which are a combination of those present for both space and ground telescopes. At altitudes of 35-40 km, convection effects are minimal and difficult to characterize. Radiation and conduction are the predominant heat transfer mechanisms reducing the thermal design options. For long duration flights payload mass is a function of power consumption making it an important optimization parameter. SuperBIT, or the Super-pressure Balloon-borne Imaging Telescope, aims to study weak lensing using a 0.5m modified Dall-Kirkham telescope capable of achieving 0.02" stability and capturing deep exposures from visible to near UV wavelengths. To achieve the theoretical stratospheric diffraction-limited resolution of 0.25", mirror deformation gradients must be kept to within 20nm. The thermal environment must thus be stable on time scales of an hour and the thermal gradients must be minimized on the telescope. SuperBIT plans to implement two types of parameter solvers; one to validate the thermal design and the other to tightly control the thermal environment.

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