CHIPS: The Cosmological H I Power Spectrum estimator

Trott, C. M. ; Pindor, B. ; Procopio, P. ; Wayth, R. B. ; Mitchell, D. A. ; McKinley, B. ; Tingay, S. J. ; Barry, N. ; Beardsley, A. P. ; Bernardi, G. ; Bowman, Judd D. ; Briggs, F. ; Cappallo, R. J. ; Carroll, P. ; de Oliveira-Costa, A. ; Dillon, Joshua S. ; Ewall-Wice, A. ; Feng, L. ; Greenhill, L. J. ; Hazelton, B. J. ; Hewitt, J. N. ; Hurley-Walker, N. ; Johnston-Hollitt, M. ; Jacobs, Daniel C. ; Kaplan, D. L. ; Kim, H. S. ; Lenc, E. ; Line, J. ; Loeb, A. ; Lonsdale, C. J. ; Morales, M. F. ; Morgan, E. ; Neben, A. R. ; Thyagarajan, Nithyanandan ; Oberoi, D. ; Offringa, A. R. ; Ord, S. M. ; Paul, S. ; Pober, J. C. ; Prabu, T. ; Riding, J. ; Udaya Shankar, N. ; Sethi, Shiv K. ; Srivani, K. S. ; Subrahmanyan, R. ; Sullivan, I. S. ; Tegmark, M. ; Webster, R. L. ; Williams, A. ; Williams, C. L. ; Wu, C. ; Wyithe, J. S. B. (2016) CHIPS: The Cosmological H I Power Spectrum estimator The Astrophysical Journal, 818 (2). Article ID 139-18 pages. ISSN 0004-637X

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Official URL: http://iopscience.iop.org/article/10.3847/0004-637...

Related URL: http://dx.doi.org/10.3847/0004-637X/818/2/139

Abstract

Detection of the cosmological neutral hydrogen signal from the Epoch of Reionization (EoR) and estimation of its basic physical parameters are principal scientific aims of many current low-frequency radio telescopes. Here we describe the Cosmological H I Power Spectrum Estimator (CHIPS), an algorithm developed and implemented with data from the Murchison Widefield Array, to compute the two-dimensional and spherically-averaged power spectrum of brightness temperature fluctuations. The principal motivations for CHIPS are the application of realistic instrumental and foreground models to form the optimal estimator, thereby maximizing the likelihood of unbiased signal estimation, and allowing a full covariant understanding of the outputs. CHIPS employs an inverse-covariance weighting of the data through the maximum likelihood estimator, thereby allowing use of the full parameter space for signal estimation ("foreground suppression"). We describe the motivation for the algorithm, implementation, application to real and simulated data, and early outputs. Upon application to a set of 3 hr of data, we set a 2σ upper limit on the EoR dimensionless power at k = 0.05 h Mpc−1 of Δ2k x 104 mK2 in the redshift range z = [6.2–6.6], consistent with previous estimates.

Item Type:Article
Source:Copyright of this article belongs to American Astronomical Society.
Keywords:Astronomical Instrumentation; Methods And Techniques; Early Universe; Methods: Statistical; Techniques: Interferometric
ID Code:114487
Deposited On:21 May 2018 06:30
Last Modified:21 May 2018 06:30

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