Paving the Way to Future Missions: the Roman Space Telescope Coronagraph Technology Demonstration

This document summarizes how far the Nancy Grace Roman Space Telescope Coronagraph Instrument (Roman CGI) will go toward demonstrating high-contrast imaging and spectroscopic requirements for potential future exoplanet direct imaging missions, illustrated by the HabEx and LUVOIR concepts. The assess...

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Veröffentlicht in:	arXiv.org 2020-09
Hauptverfasser:	Mennesson, B, Juanola-Parramon, R, Nemati, B, Ruane, G, Bailey, V P, Bolcar, M, Martin, S, Zimmerman, N, Stark, C, Pueyo, L, Benford, D, Cady, E, Crill, B, Douglas, E, Gaudi, B S, Kasdin, J, Kern, B, Krist, J, Kruk, J, Luchik, T, Macintosh, B, Mandell, A, Mawet, D, McEnery, J, Meshkat, T, Poberezhskiy, I, Rhodes, J, Riggs, A J, Turnbull, M, Roberge, A, Shi, F, Siegler, N, Stapelfeldt, K, Ygouf, M, Zellem, R, Zhao, F
Format:	Artikel
Sprache:	eng
Schlagworte:	Active control Computer simulation Coronagraphs Design specifications Extrasolar planets Masks Missions Space telescopes Subsystems Wave front control Wave fronts
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creator	Mennesson, B Juanola-Parramon, R Nemati, B Ruane, G Bailey, V P Bolcar, M Martin, S Zimmerman, N Stark, C Pueyo, L Benford, D Cady, E Crill, B Douglas, E Gaudi, B S Kasdin, J Kern, B Krist, J Kruk, J Luchik, T Macintosh, B Mandell, A Mawet, D McEnery, J Meshkat, T Poberezhskiy, I Rhodes, J Riggs, A J Turnbull, M Roberge, A Shi, F Siegler, N Stapelfeldt, K Ygouf, M Zellem, R Zhao, F
description	This document summarizes how far the Nancy Grace Roman Space Telescope Coronagraph Instrument (Roman CGI) will go toward demonstrating high-contrast imaging and spectroscopic requirements for potential future exoplanet direct imaging missions, illustrated by the HabEx and LUVOIR concepts. The assessment is made for two levels of assumed CGI performance: (i) current best estimate (CBE) as of August 2020, based on laboratory results and realistic end-to-end simulations with JPL-standard Model Uncertainty Factors (MUFs); (ii) CGI design specifications inherited from Phase B requirements. We find that the predicted performance (CBE) of many CGI subsystems compares favorably with the needs of future missions, despite providing more modest point source detection limits than future missions. This is essentially due to the challenging pupil of the Roman Space Telescope; this pupil pushes the coronagraph masks sensitivities to misalignments to be commensurate with future missions. In particular, CGI will demonstrate active low-order wavefront control and photon counting capabilities at levels of performance either higher than, or comparable to, the needs of future missions.
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subjects	Active control Computer simulation Coronagraphs Design specifications Extrasolar planets Masks Missions Space telescopes Subsystems Wave front control Wave fronts
title	Paving the Way to Future Missions: the Roman Space Telescope Coronagraph Technology Demonstration
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