1,135 research outputs found
The binned bispectrum estimator: template-based and non-parametric CMB non-Gaussianity searches
We describe the details of the binned bispectrum estimator as used for the
official 2013 and 2015 analyses of the temperature and polarization CMB maps
from the ESA Planck satellite. The defining aspect of this estimator is the
determination of a map bispectrum (3-point correlator) that has been binned in
harmonic space. For a parametric determination of the non-Gaussianity in the
map (the so-called fNL parameters), one takes the inner product of this binned
bispectrum with theoretically motivated templates. However, as a complementary
approach one can also smooth the binned bispectrum using a variable smoothing
scale in order to suppress noise and make coherent features stand out above the
noise. This allows one to look in a model-independent way for any statistically
significant bispectral signal. This approach is useful for characterizing the
bispectral shape of the galactic foreground emission, for which a theoretical
prediction of the bispectral anisotropy is lacking, and for detecting a
serendipitous primordial signal, for which a theoretical template has not yet
been put forth. Both the template-based and the non-parametric approaches are
described in this paper.Comment: Latex 42 pages with 10 figures and JCAP macros. v2: corrected small
mistake in section 5.3, changed colour scale of slice figures, other minor
changes and additions, matches published versio
Recent results and perspectives on cosmology and fundamental physics from microwave surveys
Recent cosmic microwave background data in temperature and polarization have
reached high precision in estimating all the parameters that describe the
current so-called standard cosmological model. Recent results about the
integrated Sachs-Wolfe effect from cosmic microwave background anisotropies,
galaxy surveys, and their cross-correlations are presented. Looking at fine
signatures in the cosmic microwave background, such as the lack of power at low
multipoles, the primordial power spectrum and the bounds on non-Gaussianities,
complemented by galaxy surveys, we discuss inflationary physics and the
generation of primordial perturbations in the early Universe. Three important
topics in particle physics, the bounds on neutrinos masses and parameters, on
thermal axion mass and on the neutron lifetime derived from cosmological data
are reviewed, with attention to the comparison with laboratory experiment
results. Recent results from cosmic polarization rotation analyses aimed at
testing the Einstein equivalence principle are presented. Finally, we discuss
the perspectives of next radio facilities for the improvement of the analysis
of future cosmic microwave background spectral distortion experiments.Comment: 27 pages, 9 figures. Review Article. International Journal of Modern
Physics D, in press. [Will appear also on the proceedings of the Fourteenth
Marcel Grossmann Meeting University of Rome "La Sapienza" - Rome, July 12-18,
2015 (http://www.icra.it/mg/mg14/), eds. Robert T. Jantzen, Kjell Rosquist,
Remo Ruffini. World Scientific, Singapore
The Palomar Kernel Phase Experiment: Testing Kernel Phase Interferometry for Ground-based Astronomical Observations
At present, the principal limitation on the resolution and contrast of
astronomical imaging instruments comes from aberrations in the optical path,
which may be imposed by the Earth's turbulent atmosphere or by variations in
the alignment and shape of the telescope optics. These errors can be corrected
physically, with active and adaptive optics, and in post-processing of the
resulting image. A recently-developed adaptive optics post-processing
technique, called kernel phase interferometry, uses linear combinations of
phases that are self-calibrating with respect to small errors, with the goal of
constructing observables that are robust against the residual optical
aberrations in otherwise well-corrected imaging systems. Here we present a
direct comparison between kernel phase and the more established competing
techniques, aperture masking interferometry, point spread function (PSF)
fitting and bispectral analysis. We resolve the alpha Ophiuchi binary system
near periastron, using the Palomar 200-Inch Telescope. This is the first case
in which kernel phase has been used with a full aperture to resolve a system
close to the diffraction limit with ground-based extreme adaptive optics
observations. Excellent agreement in astrometric quantities is found between
kernel phase and masking, and kernel phase significantly outperforms PSF
fitting and bispectral analysis, demonstrating its viability as an alternative
to conventional non-redundant masking under appropriate conditions.Comment: Accepted to MNRA
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