566 research outputs found
Wiener filter reloaded: fast signal reconstruction without preconditioning
We present a high performance solution to the Wiener filtering problem via a
formulation that is dual to the recently developed messenger technique. This
new dual messenger algorithm, like its predecessor, efficiently calculates the
Wiener filter solution of large and complex data sets without preconditioning
and can account for inhomogeneous noise distributions and arbitrary mask
geometries. We demonstrate the capabilities of this scheme in signal
reconstruction by applying it on a simulated cosmic microwave background (CMB)
temperature data set. The performance of this new method is compared to that of
the standard messenger algorithm and the preconditioned conjugate gradient
(PCG) approach, using a series of well-known convergence diagnostics and their
processing times, for the particular problem under consideration. This variant
of the messenger algorithm matches the performance of the PCG method in terms
of the effectiveness of reconstruction of the input angular power spectrum and
converges smoothly to the final solution. The dual messenger algorithm
outperforms the standard messenger and PCG methods in terms of execution time,
as it runs to completion around 2 and 3-4 times faster than the respective
methods, for the specific problem considered.Comment: 13 pages, 10 figures. Accepted for publication in MNRAS main journa
Probing cosmology and gravity with redshift-space distortions around voids
Cosmic voids in the large-scale structure of the Universe affect the peculiar
motions of objects in their vicinity. Although these motions are difficult to
observe directly, the clustering pattern of their surrounding tracers in
redshift space is influenced in a unique way. This allows to investigate the
interplay between densities and velocities around voids, which is solely
dictated by the laws of gravity. With the help of -body simulations and
derived mock-galaxy catalogs we calculate the average density fluctuations
around voids identified with a watershed algorithm in redshift space and
compare the results with the expectation from general relativity and the
CDM model. We find linear theory to work remarkably well in describing
the dynamics of voids. Adopting a Bayesian inference framework, we explore the
full posterior of our model parameters and forecast the achievable accuracy on
measurements of the growth rate of structure and the geometric distortion
through the Alcock-Paczynski effect. Systematic errors in the latter are
reduced from to when peculiar velocities are taken into
account. The relative parameter uncertainties in galaxy surveys with number
densities comparable to the SDSS MAIN (CMASS) sample probing a volume of
yield () and
(), respectively. At this level of precision
the linear-theory model becomes systematics dominated, with parameter biases
that fall beyond these values. Nevertheless, the presented method is highly
model independent; its viability lies in the underlying assumption of
statistical isotropy of the Universe.Comment: 38 pages, 14 figures. Published in JCAP. Referee comments
incorporated, typos corrected, references added. Considerably improved
results thanks to consideration of full covariance matrix in the MCMC
analysi
A response to arXiv:1310.2791: A self-consistent public catalogue of voids and superclusters in the SDSS Data Release 7 galaxy surveys
Recently, Nadathur & Hotchkiss (2013) submitted a paper discussing a new
cosmic void catalog. This paper includes claims about the void catalog
described in Sutter et al. (2012). In this note, we respond to those claims,
clarify some discrepancies between the text of Sutter et al. (2012) and the
most recent version of the catalog, and provide some comments on the
differences between our catalog and that of Nadathur & Hotchkiss (2013). All
updates and documentation for our catalog are available at
http://www.cosmicvoids.net.Comment: 3 pages, 1 figure, public catalog available at
http://www.cosmicvoids.ne
Precision cosmology with voids: definition, methods, dynamics
We propose a new definition of cosmic voids based on methods of Lagrangian orbit reconstruction
as well as an algorithm to find them in actual data called DynamIcal Void Analysis. Our
technique is intended to yield results which can be modelled sufficiently accurately to create
a new probe of precision cosmology. We then develop an analytical model of the ellipticity of
voids found by our method based on the Zel’dovich approximation. We measure in N-body
simulation that this model is precise at the ~0.1 per cent level for the mean ellipticity of voids
of size greater than ~4 h
^(−1) Mpc. We estimate that at this scale we are able to predict the
ellipticity with an accuracy of σ_ε ~ 0.02. Finally, we compare the distribution of void shapes
in N-body simulation for two different equations of state w of the dark energy. We conclude
that our method is far more accurate than Eulerian methods and is therefore promising as a
precision probe of dark energy phenomenology
Constraints on Cosmology and Gravity from the Dynamics of Voids
The Universe is mostly composed of large and relatively empty domains known
as cosmic voids, whereas its matter content is predominantly distributed along
their boundaries. The remaining material inside them, either dark or luminous
matter, is attracted to these boundaries and causes voids to expand faster and
to grow emptier over time. Using the distribution of galaxies centered on voids
identified in the Sloan Digital Sky Survey and adopting minimal assumptions on
the statistical motion of these galaxies, we constrain the average matter
content in the Universe today, as well as the
linear growth rate of structure at median redshift
, where is the galaxy bias ( C.L.). These values
originate from a percent-level measurement of the anisotropic distortion in the
void-galaxy cross-correlation function, , and are
robust to consistency tests with bootstraps of the data and simulated mock
catalogs within an additional systematic uncertainty of half that size. They
surpass (and are complementary to) existing constraints by unlocking
cosmological information on smaller scales through an accurate model of
nonlinear clustering and dynamics in void environments. As such, our analysis
furnishes a powerful probe of deviations from Einstein's general relativity in
the low-density regime which has largely remained untested so far. We find no
evidence for such deviations in the data at hand.Comment: 11 pages, 7 figures. Reflects published version in PRL including
Supplemental Materia
Quantitative measurement of permeabilization of living cells by terahertz attenuated total reflection
International audienceUsing Attenuated Total Reflection imaging technique in the terahertz domain, we demonstrate non-invasive, non-staining real time measurements of cytoplasm leakage during permeabilization of epithelial cells by saponin. The terahertz signal is mostly sensitive to the intracellular protein concentration in the cells, in a very good agreement with standard bicinchoninic acid protein measurements. It opens the way to in situ real time dynamics of protein content and permeabilization in live cells
Sparse sampling, galaxy bias, and voids
To study the impact of sparsity and galaxy bias on void statistics, we use a
single large-volume, high-resolution N-body simulation to compare voids in
multiple levels of subsampled dark matter, halo populations, and mock galaxies
from a Halo Occupation Distribution model tuned to different galaxy survey
densities. We focus our comparison on three key observational statistics:
number functions, ellipticity distributions, and radial density profiles. We
use the hierarchical tree structure of voids to interpret the impacts of
sampling density and galaxy bias, and theoretical and empirical functions to
describe the statistics in all our sample populations. We are able to make
simple adjustments to theoretical expectations to offer prescriptions for
translating from analytics to the void properties measured in realistic
observations. We find that sampling density has a much larger effect on void
sizes than galaxy bias. At lower tracer density, small voids disappear and the
remaining voids are larger, more spherical, and have slightly steeper profiles.
When a proper lower mass threshold is chosen, voids in halo distributions
largely mimic those found in galaxy populations, except for ellipticities,
where galaxy bias leads to higher values. We use the void density profile of
Hamaus et al. (2014) to show that voids follow a self-similar and universal
trend, allowing simple translations between voids studied in dark matter and
voids identified in galaxy surveys. We have added the mock void catalogs used
in this work to the Public Cosmic Void Catalog at http://www.cosmicvoids.net.Comment: 11 pages, 7 figures, MNRAS accepted. Minor changes from previous
version. Public catalog available at http://www.cosmicvoids.ne
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