Your search keyword '"de Mericia, Eduardo J."' showing total 4 results

1. The BINGO Project IV: Simulations for mission performance assessment and preliminary component separation steps

Author

Liccardo, Vincenzo, de Mericia, Eduardo J., Wuensche, Carlos A., Abdalla, Elcio, Abdalla, Filipe B., Barosi, Luciano, Brito, Francisco A., Queiroz, Amilcar, Villela, Thyrso, Peel, Michael W., Wang, Bin, Costa, Andre A., Ferreira, Elisa G. M., Fornazier, Karin S. F., Novaes, Camila P., Santos, Larissa, Santos, Marcelo V. dos, Remazeilles, Mathieu, Zhang, Jiajun, Dickinson, Clive, Harper, Stuart, Landim, Ricardo G., Marins, Alessandro, and Vieira, Frederico

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

The large-scale distribution of neutral hydrogen (HI) in the Universe is luminous through its 21 cm emission. The goal of the Baryon Acoustic Oscillations from Integrated Neutral Gas Observations -- BINGO -- radio telescope is to detect baryon acoustic oscillations (BAOs) at radio frequencies through 21 cm intensity mapping (IM). The telescope will span the redshift range 0.127 $< z <$ 0.449 with an instantaneous field-of-view of $14.75^{\circ} \times 6.0^{\circ}$. In this work we investigate different constructive and operational scenarios of the instrument by generating sky maps as they would be produced by the instrument. In doing this we use a set of end-to-end IM mission simulations. The maps will additionally be used to evaluate the efficiency of a component separation method (GNILC). We have simulated the kind of data that would be produced in a single-dish IM experiment such as BINGO. According to the results obtained, we have optimized the focal plane design of the telescope. In addition, the application of the GNILC method on simulated data shows that it is feasible to extract the cosmological signal across a wide range of multipoles and redshifts. The results are comparable with the standard principal component analysis method., Comment: 16 pages. Version to appear in A&A

Published

2021

2. The BINGO Project I: Baryon Acoustic Oscillations from Integrated Neutral Gas Observations

Author

Abdalla, Elcio, Ferreira, Elisa G. M., Landim, Ricardo G., Costa, Andre A., Fornazier, Karin S. F., Abdalla, Filipe B., Barosi, Luciano, Brito, Francisco A., Queiroz, Amilcar R., Villela, Thyrso, Wang, Bin, Wuensche, Carlos A., Marins, Alessandro, Novaes, Camila P., Liccardo, Vincenzo, Shan, Chenxi, Zhang, Jiajun, Zhang, Zhongli, Zhu, Zhenghao, Browne, Ian, Delabrouille, Jacques, Santos, Larissa, Santos, Marcelo V. dos, Xu, Haiguang, Anton, Sonia, Battye, Richard, Chen, Tianyue, Dickinson, Clive, Ma, Yin-Zhe, Maffei, Bruno, de Mericia, Eduardo J., Motta, Pablo, Otobone, Carlos H. N., Peel, Michael W., Roychowdhury, Sambit, Remazeilles, Mathieu, Ribeiro, Rafael M., Sang, Yu, Santos, Joao R. L., Santos, Juliana F. R. dos, Silva, Gustavo B., Vieira, Frederico, Vieira, Jordany, Xiao, Linfeng, Zhang, Xue, and Zhu, Yongkai

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics, Astrophysics - High Energy Astrophysical Phenomena, Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

Observations of the redshifted 21-cm line of neutral hydrogen (HI) are a new and powerful window of observation that offers us the possibility to map the spatial distribution of cosmic HI and learn about cosmology. BINGO (Baryon Acoustic Oscillations [BAO] from Integrated Neutral Gas Observations) is a new unique radio telescope designed to be one of the first to probe BAO at radio frequencies. BINGO has two science goals: cosmology and astrophysics. Cosmology is the main science goal and the driver for BINGO's design and strategy. The key of BINGO is to detect the low redshift BAO to put strong constraints in the dark sector models. Given the versatility of the BINGO telescope, a secondary goal is astrophysics, where BINGO can help discover and study Fast Radio Bursts (FRB) and other transients, Galactic and extragalactic science. In this paper, we introduce the latest progress of the BINGO project, its science goals, describing the scientific potential of the project in each science and the new developments obtained by the collaboration. We introduce the BINGO project and its science goals and give a general summary of recent developments in construction, science potential and pipeline development obtained by the BINGO collaboration in the past few years. We show that BINGO will be able to obtain competitive constraints for the dark sector, and also that will allow for the discovery of several FRBs in the southern hemisphere. The capacity of BINGO in obtaining information from 21-cm is also tested in the pipeline introduced here. There is still no measurement of the BAO in radio, and studying cosmology in this new window of observations is one of the most promising advances in the field. The BINGO project is a radio telescope that has the goal to be one of the first to perform this measurement and it is currently being built in the northeast of Brazil. (Abridged), Comment: 23 pages. To appear in A&A

Published

2021

3. The BINGO Project III: Optical design and optimisation of the focal plane

Author

Abdalla, Filipe B., Marins, Alessandro, Motta, Pablo, Abdalla, Elcio, Ribeiro, Rafael M., Wuensche, Carlos A., Delabrouille, Jacques, Fornazier, Karin S. F., Liccardo, Vincenzo, Maffei, Bruno, de Mericia, Eduardo J., Otobone, Carlos H. N., Santos, Juliana F. R. dos, Silva, Gustavo B., Vieira, Jordany, Barretos, João A. M., Barosi, Luciano, Brito, Francisco A., Queiroz, Amilcar R., Villela, Thyrso, Wang, Bin, Costa, Andre A., Ferreira, Elisa G. M., Landim, Ricardo G., Novaes, Camila Paiva, Peel, Michael W., Santos, Larissa, Santos, Marcelo V. dos, and Zhang, Jiajun

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

The BINGO telescope was designed to measure the fluctuations of the 21-cm radiation arising from the hyperfine transition of neutral hydrogen and aims to measure the Baryon Acoustic Oscillations (BAO) from such fluctuations, therefore serving as a pathfinder to future deeper intensity mapping surveys. The requirements for the Phase 1 of the projects consider a large reflector system (two 40 m-class dishes in a crossed-Dragone configuration), illuminating a focal plane with 28 horns to measure the sky with two circular polarisations in a drift scan mode to produce measurements of the radiation in intensity as well as the circular polarisation. In this paper we present the optical design for the instrument. We describe the intensity and polarisation properties of the beams and the optical arrangement of the horns in the focal plane to produce a homogeneous and well-sampled map after the end of Phase 1. Our analysis provides an optimal model for the location of the horns in the focal plane, producing a homogeneous and Nyquist sampled map after the nominal survey time. We arrive at an optimal configuration for the optical system, including the focal plane positioning and the beam behavior of the instrument. We present an estimate of the expected side lobes both for intensity and polarisation, as well as the effect of band averaging on the final side lobes. The cross polarisation leakage values for the final configuration allow us to conclude that the optical arrangement meets the requirements of the project. We conclude that the chosen optical design meets the requirements for the project in terms of polarisation purity, area coverage as well as homogeneity of coverage so that BINGO can perform a successful BAO experiment. We further conclude that the requirements on the placement and r.m.s. error on the mirrors are also achievable so that a successful experiment can be conducted.(Abridged), Comment: 22 pages. Accepted for publication in A&A

Published

2021

4. The BINGO Project II: Instrument Description

Author

Wuensche, Carlos A., Villela, Thyrso, Abdalla, Elcio, Liccardo, Vincenzo, Vieira, Frederico, Browne, Ian, Peel, Michael W., Radcliffe, Christopher, Abdalla, Filipe B., Marins, Alessandro, Barosi, Luciano, Brito, Francisco A., Queiroz, Amilcar R., Wang, Bin, Costa, Andre A., Ferreira, Elisa G. M., Fornazier, Karin S. F., Landim, Ricardo G., Novaes, Camila P., Santos, Larissa, Santos, Marcelo V. dos, Zhang, Jiajun, Chen, Tianyue, Delabrouille, Jacques, Dickinson, Clive, de Gasperis, Giancarlo, Gurjão, Edmar C., Harper, Stuart, Ma, Yin-Zhe, Machado, Telmo, Maffei, Bruno, de Mericia, Eduardo J., Monstein, Christian, Motta, Pablo, Otobone, Carlos H. N., Reitano, Luiz A., Remazeilles, Mathieu, Roychowdhury, Sambit, Santos, João R. L., Serres, Alexandre J. R., Souza, Andreia P., Strauss, Cesar, Vieira, Jordany, and Xu, Haiguang

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

The measurement of diffuse 21-cm radiation from the hyperfine transition of neutral hydrogen (HI signal) in different redshifts is an important tool for modern cosmology. However, detecting this faint signal with non-cryogenic receivers in single-dish telescopes is a challenging task. The BINGO (Baryon Acoustic Oscillations from Integrated Neutral Gas Observations) radio telescope is an instrument designed to detect baryonic acoustic oscillations (BAOs) in the cosmological HI signal, in the redshift interval $0.127 \le z \le 0.449$. This paper describes the BINGO radio telescope, including the current status of the optics, receiver, observational strategy, calibration, and the site. BINGO has been carefully designed to minimize systematics, being a transit instrument with no moving dishes and 28 horns operating in the frequency range $980 \le \nu \le 1260$ MHz. Comprehensive laboratory tests were conducted for many of the BINGO subsystems and the prototypes of the receiver chain, horn, polarizer, magic tees, and transitions have been successfully tested between 2018 - 2020. The survey was designed to cover $\sim 13\%$ of the sky, with the primary mirror pointing at declination $\delta=-15^{\circ}$. The telescope will see an instantaneous declination strip of $14.75^{\circ}$. The results of the prototype tests closely meet those obtained during the modeling process, suggesting BINGO will perform according to our expectations. After one year of observations with a $60\%$ duty cycle and 28 horns, BINGO should achieve an expected sensitivity of 102 $\mu K$ per 9.33 MHz frequency channel, one polarization, and be able to measure the HI power spectrum in a competitive time frame., Comment: 13 pages, accepted for publication in A&A

Published

2021