5,697 research outputs found
Measuring the transition to homogeneity with photometric redshift surveys
We study the possibility of detecting the transition to homogeneity using
photometric redshift catalogs. Our method is based on measuring the fractality
of the projected galaxy distribution, using angular distances, and relies only
on observable quantites. It thus provides a way to test the Cosmological
Principle in a model-independent unbiased way. We have tested our method on
different synthetic inhomogeneous catalogs, and shown that it is capable of
discriminating some fractal models with relatively large fractal dimensions, in
spite of the loss of information due to the radial projection. We have also
studied the influence of the redshift bin width, photometric redshift errors,
bias, non-linear clustering, and surveyed area, on the angular homogeneity
index H2 ({\theta}) in a {\Lambda}CDM cosmology. The level to which an upcoming
galaxy survey will be able to constrain the transition to homogeneity will
depend mainly on the total surveyed area and the compactness of the surveyed
region. In particular, a Dark Energy Survey (DES)-like survey should be able to
easily discriminate certain fractal models with fractal dimensions as large as
D2 = 2.95. We believe that this method will have relevant applications for
upcoming large photometric redshift surveys, such as DES or the Large Synoptic
Survey Telescope (LSST).Comment: 14 pages, 14 figure
Type-4 spinors: transmuting from Elko to single-helicity spinors
In this communication we briefly report an unexpected theoretical discovery
which emerge from the mapping of Elko mass-dimension-one spinors into single
helicity spinors. Such procedure unveils a class of spinor which is classified
as type-4 spinor field within Lounesto classification. In this paper we explore
the underlying physical and mathematical contents of the type-4 spinor.Comment: 9 pages, 0 figure
A parametric approach for the identification of single-charged isotopes with AMS-02
Measurements of the isotopic composition of single-charged cosmic rays
provide important insights in the propagation processes. However, the isotopic
identification is challenging due to the one hundred times greater abundance of
protons when compared to deuterons, the only stable isotope of hydrogen. Taking
advantage of the precise measurements of the velocity and momentum in the Alpha
Magnetic Spectrometer (AMS-02), a particle physics detector operating aboard
the International Space Station since May 2011, we describe a parametric
template fit method, which takes into account systematic uncertainties such as
the fragmentation of particles inside AMS-02 and eventual differences between
data and simulation through the use of nuisance parameters. With this method we
are also able to assess the AMS-02 performance in terms of mass resolution,
showing that it is able to separate the isotopes of hydrogen up to 10 GeV/n.Comment: Accepted for publication in Nuclear Instruments and Methods in
Physics Research Section
Machine learning approach to the background reduction in singly charged cosmic-ray isotope measurements with AMS-02
Studying the isotopic composition of single-charge cosmic rays (CRs) provides essential data to investigate the CR propagation processes in our Galaxy. While current measurements are rare above 4 GeV/nucleon, the Alpha Magnetic Spectrometer (AMS-02) is able to measure the isotopic fluxes up to 10 GeV/n by combining the momentum measured by the silicon tracker with the precise measurements of the velocity provided by its Ring Imaging Cherenkov Detector (RICH). The correct measurement of the particles’ velocity is essential for identifying isotopes through their mass. This is particularly challenging for single-charge particles due to the low number of photons they produce in their Cherenkov rings, which makes the reconstruction easily disrupted by noise. Hence, identifying the sources and cleaning the sample from the background is essential for ensuring the quality of the rings. In this paper, we propose a novel approach to track the events whose mass is misidentified due to interactions inside the AMS-02 detector. Based on the actual location of these interactions, we propose a novel strategy to mitigate the background effectively and with high efficiency, which includes using cut-based selection criteria and a multivariate estimator based on the signals detected by the RICH.</p
Iterative-Bayesian unfolding of isotopic cosmic-ray fluxes measured by AMS-02
The measurement of the isotopic composition of cosmic rays (CRs) provides
essential insights the understanding of the origin and propagation of these
particles, namely the CR source spectra, the propagation processes and the
galactic halo size. The Alpha Magnetic Spectrometer (AMS-02), a CR detector
operating aboard the International Space Station since May 2011, has the
capability of performing these measurements due to its precise determination of
the velocity provided by its Time of Flight (TOF) and Ring Imaging Cherenkov
(RICH) detector. The correct interpretation of the data requires the
measurements to be deconvoluted from the instrumental effects. The unique
design of AMS-02, with more than one subdetector being used to measure the same
flux, requires a novel approach to unfold the measured fluxes. In this work, we
describe an iterative-Bayesian unfolding method applied in the context of
isotopic flux measurements in AMS-02. The accuracy of the method is assessed
using a simulated flux based on previous measurements and a full detector
response function. We introduce a non-parametric regularization method for the
detector response functions, as well as a single, smooth prior flux covering
the full range of measurements from both detectors, TOF and RICH. In addition,
the estimation of the errors and a discussion about the performance of the
method are also shown, demonstrating that the method is fast and reliable,
allowing for the recovery of the true fluxes in the full energy range.Comment: Submitted to NIM
A conjugate gradient method for the solution of the non-LTE line radiation transfer problem
This study concerns the fast and accurate solution of the line radiation
transfer problem, under non-LTE conditions. We propose and evaluate an
alternative iterative scheme to the classical ALI-Jacobi method, and to the
more recently proposed Gauss-Seidel and Successive Over-Relaxation (GS/SOR)
schemes. Our study is indeed based on the application of a preconditioned
bi-conjugate gradient method (BiCG-P). Standard tests, in 1D plane parallel
geometry and in the frame of the two-level atom model, with monochromatic
scattering, are discussed. Rates of convergence between the previously
mentioned iterative schemes are compared, as well as their respective timing
properties. The smoothing capability of the BiCG-P method is also demonstrated.Comment: Research note: 4 pages, 5 figures, accepted to A&
A Substantial Amount of Hidden Magnetic Energy in the Quiet Sun
Deciphering and understanding the small-scale magnetic activity of the quiet
solar photosphere should help to solve many of the key problems of solar and
stellar physics, such as the magnetic coupling to the outer atmosphere and the
coronal heating. At present, we can see only of the complex
magnetism of the quiet Sun, which highlights the need to develop a reliable way
to investigate the remaining 99%. Here we report three-dimensional radiative
tranfer modelling of scattering polarization in atomic and molecular lines that
indicates the presence of hidden, mixed-polarity fields on subresolution
scales. Combining this modelling with recent observational data we find a
ubiquitous tangled magnetic field with an average strength of G,
which is much stronger in the intergranular regions of solar surface convection
than in the granular regions. So the average magnetic energy density in the
quiet solar photosphere is at least two orders of magnitude greater than that
derived from simplistic one-dimensional investigations, and sufficient to
balance radiative energy losses from the solar chromosphere.Comment: 21 pages and 2 figures (letter published in Nature on July 15, 2004
Using global analysis, partial specifications, and an extensible assertion language for program validation and debugging
We discuss a framework for the application of abstract interpretation as an aid during program development, rather than in the more traditional application of program optimization. Program validation and detection of errors is first performed statically by comparing (partial) specifications written in terms of assertions against information obtained from (global) static analysis of the program. The results of this process are expressed in the user assertion language. Assertions (or parts of assertions) which cannot be checked statically are translated into run-time tests. The framework allows the use of assertions to be optional. It also allows using very general properties in assertions, beyond the predefined set understandable by the static analyzer and including properties defined by user programs. We also report briefly on an implementation of the framework. The resulting tool generates and checks assertions for Prolog, CLP(R), and CHIP/CLP(fd) programs, and integrates compile-time and run-time checking in a uniform way. The tool allows using properties such as types, modes, non-failure, determinacy,
and computational cost, and can treat modules separately, performing incremental analysis
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