Your search keyword '"BOOMERanG experiment"' showing total 3 results

1. High-Latitude Galactic Dust Emission in the BOOMERANG Maps

Author

T. E. Montroy, M. Giacometti, A. Boscaleri, Philip Daniel Mauskopf, F. Piacentini, Calvin B. Netterfield, Silvia Masi, Enzo Pascale, P. de Bernardis, B. P. Crill, Peter A. R. Ade, Andrew E. Lange, Eric Hivon, James J. Bock, J. E. Ruhl, Simon Prunet, and Viktor Hristov

Subjects

Physics, Brightness, 010308 nuclear & particles physics, Astrophysics (astro-ph), Cosmic microwave background, Extrapolation, BOOMERanG experiment, FOS: Physical sciences, Spectral density, Astronomy and Astrophysics, Astrophysics::Cosmology and Extragalactic Astrophysics, Astrophysics, 7. Clean energy, 01 natural sciences, Latitude, 13. Climate action, Space and Planetary Science, 0103 physical sciences, Beta (velocity), cosmic microwave background, dust, extinction, infrared : ism : continuum, infrared: ism: continuum, submillimeter, 010303 astronomy & astrophysics, Astrophysics::Galaxy Astrophysics, Cosmic dust

Abstract

We present mm-wave observations obtained by the BOOMERanG experiment of Galactic emission at intermediate and high (b < -20 deg) Galactic latitudes. We find that this emission is well correlated with extrapolation of the IRAS-DIRBE maps, and is spectrally consistent with thermal emission from interstellar dust (ISD). The ISD brightness in the 410 GHz map has an angular power spectrum c_l = A l^{-beta} with 2 < beta < 3. At 150 GHz and at multipoles ell \sim 200 the angular power spectrum of the IRAS-correlated dust signal is estimated to be l(l+1)c_l/2 pi = (3.7 \pm 2.9) uK^2. This is negligible with respect to the CMB signal measured by the same experiment l(l+1)c_l/2 pi = (4700 \pm 540) uK^2. For the uncorrelated dust signal we set an upper limit to the contribution to the CMB power at 150GHz and l \sim 200 of l(l+1)c_l/2 pi < 3 uK^2 at 95% C.L. .

Published

2001

2. Fast Cosmic Microwave Background Analyses via Correlation Functions

Author

J. Richard Bond, Alexander S. Szalay, Simon Prunet, Dmitry Pogosyan, and István Szapudi

Subjects

Physics, Theoretical physics, Minimum-variance unbiased estimator, Pixel, Bias of an estimator, Space and Planetary Science, Cosmic microwave background, Monte Carlo method, BOOMERanG experiment, Spectral density, Astronomy and Astrophysics, Higher-order statistics, Algorithm

Abstract

We propose and implement a fast, universally applicable method for extracting the angular power spectrum from cosmic microwave background temperature maps by first estimating the correlation function . Our C y(v) procedure recovers the using (but potentially ) operations, where N is the number of pixels. This 2 C NN log N is in contrast with standard maximum likelihood techniques that require operations. Our method makes no 3 N special assumptions about the map, unlike present-day fast techniques that rely on symmetries of the underlying noise matrix, sky coverage, scanning strategy, and geometry. This makes analysis of megapixel maps without symmetries possible for the first time. The key element of our technique is the accurate multipole decomposition of . The error bars and cross-correlations are found by using a Monte Carlo approach. We applied our y(v) C technique to a large number of simulated maps with BOOMERanG (Balloon Observations Of Millimetric Radiation and Geophysics) sky coverage in 81,000 pixels. We used a diagonal noise matrix, with approximately the same amplitude as the BOOMERanG experiment. These studies demonstrate that our technique provides an unbiased estimator of the . Even though our method is approximate, the error bars obtained are nearly optimal, C and they converged only after a few tens of Monte Carlo realizations. Our method is directly applicable for the nondiagonal noise matrix. This and other generalizations, such as minimum variance weighting schemes, polarization, and higher order statistics, are also discussed. Subject headings: cosmic microwave background — cosmology: theory — methods: statistical On-line material: color figures

Published

2001

3. A Measurement of Omega from the North American Test Flight of Boomerang

Author

A. Boscaleri, Calvin B. Netterfield, F. Piacentini, G. De Troia, M. Giacometti, Alessandro Melchiorri, Andrew E. Lange, L. Miglio, Silvia Masi, Viktor Hristov, Peter A. R. Ade, G. de Gasperis, P. C. Farese, Pedro G. Ferreira, Philip Daniel Mauskopf, Giovanni Romeo, Enzo Pascale, A. H. Jaffe, P. de Bernardis, J. E. Ruhl, Ken Ganga, B. P. Crill, Nicola Vittorio, Julian Borrill, and James J. Bock

Subjects

Astrophysics and Astronomy, Cold dark matter, Cosmic microwave background, BOOMERanG experiment, FOS: Physical sciences, Astrophysics, Cosmological constant, General Relativity and Quantum Cosmology (gr-qc), Astrophysics::Cosmology and Extragalactic Astrophysics, 01 natural sciences, Omega, General Relativity and Quantum Cosmology, Methods: Data Analysis, Settore FIS/05 - Astronomia e Astrofisica, 0103 physical sciences, 010303 astronomy & astrophysics, Physics, 010308 nuclear & particles physics, Cosmology: Dark Matter, Astrophysics (astro-ph), Spectral density, Astronomy and Astrophysics, Cosmology: Cosmic Microwave Background, Redshift, Supernova, Cosmology: Cosmic Microwave Background, Cosmology: Dark Matter, Methods: Data Analysis, Space and Planetary Science

Abstract

We use the angular power spectrum of the Cosmic Microwave Background, measured during the North American test flight of the BOOMERANG experiment, to constrain the geometry of the universe. Within the class of Cold Dark Matter models, we find that the overall fractional energy density of the universe, Omega, is constrained to be 0.85 < Omega < 1.25 at the 68% confidence level. Combined with the COBE measurement and the high redshift supernovae data we obtain new constraints on the fractional matter density and the cosmological constant., 4 pages, 3 figures LaTeX, emulateapj.sty

Published

1999