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Main Authors: Coppi, Gabriele, Dachlythra, Nadia, Nati, Federico, Dünner-Planella, Rolando, Adler, Alexandre E., Errard, Josquin, Galitzki, Nicholas, Li, Yunyang, Petroff, Matthew A., Simon, Sara M., Sang, Ema Tsang King, Aguilar, Amalia Villarrubia, Wollack, Edward J., Zannoni, Mario
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2502.14473
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author Coppi, Gabriele
Dachlythra, Nadia
Nati, Federico
Dünner-Planella, Rolando
Adler, Alexandre E.
Errard, Josquin
Galitzki, Nicholas
Li, Yunyang
Petroff, Matthew A.
Simon, Sara M.
Sang, Ema Tsang King
Aguilar, Amalia Villarrubia
Wollack, Edward J.
Zannoni, Mario
author_facet Coppi, Gabriele
Dachlythra, Nadia
Nati, Federico
Dünner-Planella, Rolando
Adler, Alexandre E.
Errard, Josquin
Galitzki, Nicholas
Li, Yunyang
Petroff, Matthew A.
Simon, Sara M.
Sang, Ema Tsang King
Aguilar, Amalia Villarrubia
Wollack, Edward J.
Zannoni, Mario
contents Current- and next-generation Cosmic Microwave Background (CMB) experiments will measure polarization anisotropies with unprecedented sensitivities. The need for high precision in these measurements underscores the importance of gaining a comprehensive understanding of instrument properties, with a particular emphasis on the study of the beam properties and, in particular, their polarization characteristics, and the measurement of the polarization angle. In this context, a major challenge lies in the scarcity of millimeter polarized astrophysical sources with sufficient brightness and calibration knowledge to meet the stringent accuracy requirements of future CMB missions. This led to the development of a drone-borne calibration source designed for frequency band centered on approximately 90 GHz band, matching a commonly used channel in ground based CMB measurements. The PROTOtype CALibrator for Cosmology, PROTOCALC, has undergone thorough in-lab testing, and its properties have been subsequently modeled through simulation software integrated into the standard Simons Observatory (SO) analysis pipeline. Moreover, the PROTOCALC system has been tested in the field, having been deployed twice on calibration campaigns with CMB telescopes in the Atacama desert. The data collected constrain the roll angle of the source with a statistical accuracy of $0.045^\circ$.
format Preprint
id arxiv_https___arxiv_org_abs_2502_14473
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle PROTOCALC, A W-band polarized calibrator for CMB Telescopes: application to Simons Observatory and CLASS
Coppi, Gabriele
Dachlythra, Nadia
Nati, Federico
Dünner-Planella, Rolando
Adler, Alexandre E.
Errard, Josquin
Galitzki, Nicholas
Li, Yunyang
Petroff, Matthew A.
Simon, Sara M.
Sang, Ema Tsang King
Aguilar, Amalia Villarrubia
Wollack, Edward J.
Zannoni, Mario
Instrumentation and Methods for Astrophysics
Cosmology and Nongalactic Astrophysics
Current- and next-generation Cosmic Microwave Background (CMB) experiments will measure polarization anisotropies with unprecedented sensitivities. The need for high precision in these measurements underscores the importance of gaining a comprehensive understanding of instrument properties, with a particular emphasis on the study of the beam properties and, in particular, their polarization characteristics, and the measurement of the polarization angle. In this context, a major challenge lies in the scarcity of millimeter polarized astrophysical sources with sufficient brightness and calibration knowledge to meet the stringent accuracy requirements of future CMB missions. This led to the development of a drone-borne calibration source designed for frequency band centered on approximately 90 GHz band, matching a commonly used channel in ground based CMB measurements. The PROTOtype CALibrator for Cosmology, PROTOCALC, has undergone thorough in-lab testing, and its properties have been subsequently modeled through simulation software integrated into the standard Simons Observatory (SO) analysis pipeline. Moreover, the PROTOCALC system has been tested in the field, having been deployed twice on calibration campaigns with CMB telescopes in the Atacama desert. The data collected constrain the roll angle of the source with a statistical accuracy of $0.045^\circ$.
title PROTOCALC, A W-band polarized calibrator for CMB Telescopes: application to Simons Observatory and CLASS
topic Instrumentation and Methods for Astrophysics
Cosmology and Nongalactic Astrophysics
url https://arxiv.org/abs/2502.14473