Euclid Structural-Thermal-Optical Performance

Euclid Collaboration: A. Anselmi , R. Laureijs , G. D. Racca , G. Costa , L. Courcould Mifsud , J.-C. Cuillandre , M. Gottero , H. Hoekstra

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K. Kuijken V. Mareschi L. Miller S. Mottini D. Stramaccioni B. Altieri A. Amara S. Andreon N. Auricchio C. Baccigalupi M. Baldi A. Balestra S. Bardelli R. Bender A. Biviano E. Branchini M. Brescia S. Camera G. Canas-Herrera V. Capobianco C. Carbone J. Carretero M. Castellano G. Castignani S. Cavuoti A. Cimatti C. Colodro-Conde G. Congedo C. J. Conselice L. Conversi Y. Copin F. Courbin H. M. Courtois M. Cropper A. Da Silva H. Degaudenzi G. De Lucia H. Dole F. Dubath F. Ducret C. A. J. Duncan X. Dupac S. Dusini S. Escoffier M. Fabricius M. Farina R. Farinelli F. Faustini S. Ferriol F. Finelli N. Fourmanoit M. Frailis E. Franceschi M. Fumana S. Galeotta K. George B. Gillis C. Giocoli J. Gracia-Carpio A. Grazian F. Grupp S. V. H. Haugan J. Hoar W. Holmes F. Hormuth A. Hornstrup K. Jahnke M. Jhabvala E. Keihanen S. Kermiche A. Kiessling R. Kohley B. Kubik M. Kunz H. Kurki-Suonio A. M. C. Le Brun S. Ligori P. B. Lilje V. Lindholm I. Lloro G. Mainetti D. Maino E. Maiorano O. Mansutti O. Marggraf M. Martinelli N. Martinet F. Marulli R. J. Massey E. Medinaceli S. Mei Y. Mellier M. Meneghetti E. Merlin G. Meylan A. Mora M. Moresco L. Moscardini R. Nakajima C. Neissner R. C. Nichol S.-M. Niemi C. Padilla S. Paltani F. Pasian K. Pedersen W. J. Percival V. Pettorino S. Pires G. Polenta M. Poncet L. A. Popa F. Raison R. Rebolo A. Renzi J. Rhodes G. Riccio E. Romelli M. Roncarelli C. Rosset E. Rossetti R. Saglia Z. Sakr J.-C. Salvignol A. G. Sanchez D. Sapone B. Sartoris M. Schirmer P. Schneider T. Schrabback A. Secroun G. Seidel S. Serrano C. Sirignano G. Sirri J. Skottfelt L. Stanco J. Steinwagner P. Tallada-Cresp D. Tavagnacco A. N. Taylor H. I. Teplitz I. Tereno N. Tessore S. Toft R. Toledo-Moreo F. Torradeflot I. Tutusaus E. A. Valentijn L. Valenziano J. Valiviita T. Vassallo G. Verdoes Kleijn A. Veropalumbo Y. Wang J. Weller A. Zacchei G. Zamorani E. Zucca M. Ballardini M. Bolzonella E. Bozzo C. Burigana R. Cabanac A. Cappi J. A. Escartin Vigo L. Gabarra W. G. Hartley J. Martin Fleitas S. Matthew N. Mauri R. B. Metcalf A. Pezzotta M. Pontinen I. Risso V. Scottez M. Sereno M. Tenti M. Viel M. Wiesmann Y. Akrami I. T. Andika S. Anselmi M. Archidiacono F. Atrio-Barandela D. Bertacca M. Bethermin A. Blanchard L. Blot M. Bonici S. Borgani M. L. Brown S. Bruton A. Calabro B. Camacho Quevedo F. Caro C. S. Carvalho T. Castro F. Cogato S. Conseil A. R. Cooray O. Cucciati S. Davini G. Desprez A. Diaz-Sanchez J. J. Diaz S. Di Domizio J. M. Diego M. Y. Elkhashab A. Enia Y. Fang A. G. Ferrari A. Finoguenov A. Franco K. Ganga J. Garcia-Bellido T. Gasparetto E. Gaztanaga F. Giacomini F. Gianotti G. Gozaliasl M. Guidi C. M. Gutierrez A. Hall H. Hildebrandt J. Hjorth J. J. E. Kajava Y. Kang V. Kansal D. Karagiannis K. Kiiveri J. Kim C. C. Kirkpatrick S. Kruk J. Le Graet L. Legrand M. Lembo F. Lepori G. Leroy G. F. Lesci J. Lesgourgues L. Leuzzi T. I. Liaudat S. J. Liu A. Loureiro J. Macias-Perez M. Magliocchetti F. Mannucci R. Maoli C. J. A. P. Martins L. Maurin M. Miluzio P. Monaco A. Montoro C. Moretti G. Morgante S. Nadathur K. Naidoo A. Navarro-Alsina S. Nesseris D. Paoletti F. Passalacqua K. Paterson L. Patrizii A. Pisani D. Potter S. Quai M. Radovich S. Sacquegna M. Sahlen D. B. Sanders E. Sarpa A. Schneider D. Sciotti E. Sellentin L. C. Smith K. Tanidis G. Testera R. Teyssier S. Tosi A. Troja M. Tucci C. Valieri A. Venhola D. Vergani G. Verza P. Vielzeuf N. A. Walton

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classification 🌌 astro-ph.IM

keywords analysisperformanceimagestoptelescopeerrorqualityspacecraft

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The Euclid system performance is defined in terms of image quality metrics tuned to the weak gravitational lensing (WL) cosmological probe. WL induces stringent requirements on the shape and stability of the VIS instrument system point spread function (PSF). The PSF is affected by error contributions from the telescope, the focal plane and image motion, and is controlled by a global error budget with error allocations to each contributor. Aims. During spacecraft development, we verified through a structural-thermal-optical performance (STOP) analysis that the built and verified telescope with its spacecraft interface meets the in-orbit steady-state and transient image quality requirements. Methods. For the purposes of the STOP analysis, a detailed finite-element mathematical model was set up and a standard set of test cases, both steady-state and transient, was defined, comprising combinations of worst-case boundary conditions. Results. The STOP analysis addressed the interaction of all spacecraft components in transmitting temperature-induced loads that lead to optical train deformation. The results of the prelaunch analysis demonstrated that temperature-induced optical perturbations will be well below the allowable limits for all permitted observing conditions. During the first year in orbit, we used the STOP analysis predictions to help interpret the measured performance as a function of environmental variables. Unpredicted disturbances were discovered and unexpected sensitivities were revealed. In-orbit temperature variations are small (<300 mK) and so are their effects on the telescope structure, but they are detected in the time histories of the image quality metrics and are a non-negligible factor in the PSF stability budget demanded by the WL science. Taking everything into account, our analysis confirms the excellent overall performance of the telescope.

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