714 research outputs found
A complex idea of human Being : The contribution of neuroscience and ecological social and human approach in the construction of competent and inclusive educational context
According to the current lines of contemporary research, the aim of the framework of inclusive education is to respond to the diversity and learning differences of all students, through a different environmental organization for everyone. Brain development is largely a process that depends on experience, in both positive and negative terms (Oliviero, 2017). According to the principle of neuronal plasticity, the brain modifies its structure on the basis of environmental stimuli: in fact, it is environmental and interpersonal experiences that modify our brain structures. In the educational field, it is therefore essential to structure contexts and learning opportunities that generate interest, curiosity, and participation, in heterogeneous environments such as that of today’s school, but respecting the development of each student. The contribution of contemporary neuroscience allows, today, embody the idea of a complex being human. The relationships and the mediators that are used at school, are the signs that students received. That can stimulate the perceptive apparatus and support the development of identity and the relationship between similar (inter-objectivity). In this work we will present, through the perspective of the principles of Universal Design (Rose and Meyer, 2002) how an active, multi-perspective and varied learning, stimulating learning, participation, and a development of soft skills, through the design of educational contexts and using a different methods that enhance diversity
Casting Light on the Hidden Bilevel Combinatorial Structure of the Capacitated Vertex Separator Problem
Given an undirected graph, we study the capacitated vertex separator problem
that asks to find a subset of vertices of minimum cardinality, the removal of which induces a
graph having a bounded number of pairwise disconnected shores (subsets of vertices) of
limited cardinality. The problem is of great importance in the analysis and protection of communication or social networks against possible viral attacks and for matrix decomposition algorithms. In this article, we provide a new bilevel interpretation of the problem and model it
as a two-player Stackelberg game in which the leader interdicts the vertices (i.e., decides on
the subset of vertices to remove), and the follower solves a combinatorial optimization problem on the resulting graph. This approach allows us to develop a computational framework
based on an integer programming formulation in the natural space of the variables. Thanks
to this bilevel interpretation, we derive three different families of strengthening inequalities
and show that they can be separated in polynomial time. We also show how to extend these
results to a min-max version of the problem. Our extensive computational study conducted
on available benchmark instances from the literature reveals that our new exact method is
competitive against the state-of-the-art algorithms for the capacitated vertex separator problem and is able to improve the best-known results for several difficult classes of instances.
The ideas exploited in our framework can also be extended to other vertex/edge deletion/
insertion problems or graph partitioning problems by modeling them as two-player Stackel-
berg games and solving them through bilevel optimization
IBIS/PICsIT in-flight performances
PICsIT (Pixellated Imaging CaeSium Iodide Telescope) is the high energy
detector of the IBIS telescope on-board the INTEGRAL satellite. PICsIT operates
in the gamma-ray energy range between 175 keV and 10 MeV, with a typical energy
resolution of 10% at 1 MeV, and an angular resolution of 12 arcmin within a
\~100 square degree field of view, with the possibility to locate intense point
sources in the MeV region at the few arcmin level. PICsIT is based upon a
modular array of 4096 independent CsI(Tl) pixels, ~0.70 cm^2 in cross-section
and 3 cm thick. In this work, the PICsIT on-board data handling and science
operative modes are described. This work presents the in-flight performances in
terms of background count spectra, sensitivity limit, and imaging capabilities.Comment: 8 pages, 4 figures. Accepted for publication on A&A, special issue on
First Science with INTEGRA
BeppoSAX view of NGC 526A: a Seyfert 1.9 galaxy with a flat spectrum
In the present work we report the BeppoSAX observation of the Seyfert 1.9
galaxy NGC 526A in the band 0.1-150 keV. The high energy instrument onboard,
PDS, has succeeded in measuring for the first time the spectrum of this source
in the 13-150 keV range. The combined analysis of all Narrow Field Instruments
provides a power law spectral index of ~ 1.6 and confirms the flat spectral
nature of this source. Although NGC 526A varies strongly in the 2-10 keV over
period of months/years, its spectral shape remains constant over these
timescales. An Fe K-alpha line, characterized by a complex structure, has been
detected in the 6-7 keV range. The line, which has an equivalent width of 120
eV, is not compatible with being produced in an absorbing torus with N_H ~
10^22 cm^-2, but most likely originates by reflection in an accretion disk
viewed at an intermediate inclination angle of ~ 42 deg. The reflection
component is however small (R < 0.7) and so it is not sufficient to steepen the
spectrum to photon index values more typical of AGNs. Instead, we find that the
data are more consistent with a flat power law spectrum cut-off at around 100
keV plus a small reflection component which could explain the observed iron
line. Thus NGC 526A is the only bona-fide Seyfert 2 galaxy which maintains a
"flat spectrum" even when broad band data are considered: in this sense its
properties, with respect to the general class of Seyfert 2's, are analogous to
those of NGC 4151 with respect to the vast majority of Seyfert 1's.Comment: 8 pages, 6 PostScript figures, Latex manuscript, new A&A file style
included, accepted for publication on Astronomy and Astrophysic
Design and construction of a new metering hot box for the in situ hygrothermal measurement in dynamic conditions of historic masonries
The main purpose of the HeLLo project is to contribute to data available on the literature on the real hygrothermal behavior of historic walls and the suitability of insulation technologies. Furthermore, it also aims at minimizing the energy simulation errors at the design phase and at improving their conservation features. In this framework, one of the preliminary activities of the study is the creation of a real in situ hot box to measure and analyze different insulation technologies applied to a real historic wall, to quantify the hygrothermal performance of a masonry building. Inside this box, 'traditional' experiments can be carried out: recording heat flux, surface temperature, and air temperatures, as well as relative humidity values through the use of a new sensing system (composed of thermocouples and temperature/relative humidity combined sensors). Within this paper, the process of development, construction, and validation of this new metering box is exhibited. The new hot box, specifically studied for historic case studies, when compared to other boxes, presents other advantages compared to previous examples, widely exemplified
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