8,915 research outputs found
A two-dimensional Fermi liquid with attractive interactions
We realize and study an attractively interacting two-dimensional Fermi
liquid. Using momentum resolved photoemission spectroscopy, we measure the
self-energy, determine the contact parameter of the short-range interaction
potential, and find their dependence on the interaction strength. We
successfully compare the measurements to a theoretical analysis, properly
taking into account the finite temperature, harmonic trap, and the averaging
over several two-dimensional gases with different peak densities
Simple “Market Value” Bargaining Model for Weighted Voting Games: Characterization and Limit Theorems
Feld, Grofman and Ray (2003) offer a bargaining model for weighted voting games that is a close relative of the nucleolus and the kernel. They look for a set of weights that preserves winning coalitions that has the property of minimizing the difference between the weight of the smallest and the weight of the largest Minimum Winning Coalition. They claim that such a set of weights provides an a priori measure of a weighted voter’s bribeworthiness or market
value. Here, after reviewing the basic elements of their model, we provide a
characterization result for this model and show its links to other bargaining model
approaches in the literature. Then we offer some limit results showing that, with certain reasonable conditions on the distributions of weights, as the size of the voting body increases, the values of bribeworthiness we calculate will approach both the weights themselves and the Banzhaf scores for the weighted voting game. We also show that, even for relatively small groups using weighted voting, such as the membership of the European Council of Ministers (and its
precedessors) 1958-2003, similarities among the usual a priori power scores,
bribeworthiness/market value, and the weights themselves, will be quite strong
Bayesian Surprise in Indoor Environments
This paper proposes a novel method to identify unexpected structures in 2D
floor plans using the concept of Bayesian Surprise. Taking into account that a
person's expectation is an important aspect of the perception of space, we
exploit the theory of Bayesian Surprise to robustly model expectation and thus
surprise in the context of building structures. We use Isovist Analysis, which
is a popular space syntax technique, to turn qualitative object attributes into
quantitative environmental information. Since isovists are location-specific
patterns of visibility, a sequence of isovists describes the spatial perception
during a movement along multiple points in space. We then use Bayesian Surprise
in a feature space consisting of these isovist readings. To demonstrate the
suitability of our approach, we take "snapshots" of an agent's local
environment to provide a short list of images that characterize a traversed
trajectory through a 2D indoor environment. Those fingerprints represent
surprising regions of a tour, characterize the traversed map and enable indoor
LBS to focus more on important regions. Given this idea, we propose to use
"surprise" as a new dimension of context in indoor location-based services
(LBS). Agents of LBS, such as mobile robots or non-player characters in
computer games, may use the context surprise to focus more on important regions
of a map for a better use or understanding of the floor plan.Comment: 10 pages, 16 figure
Scale invariance and viscosity of a two-dimensional Fermi gas
We investigate the collective excitations of a harmonically trapped
two-dimensional Fermi gas from the collisionless (zero sound) to the
hydrodynamic (first sound) regime. The breathing mode, which is sensitive to
the equation of state, is observed at a frequency two times the dipole mode
frequency for a large range of interaction strengths and temperatures, and the
amplitude of the breathing mode is undamped. This provides evidence for a
dynamical SO(2,1) scaling symmetry of the two-dimensional Fermi gas. Moreover,
we investigate the quadrupole mode to measure the shear viscosity of the
two-dimensional gas and study its temperature dependence
Efficient Immunization Strategies for Computer Networks and Populations
We present an effective immunization strategy for computer networks and
populations with broad and, in particular, scale-free degree distributions. The
proposed strategy, acquaintance immunization, calls for the immunization of
random acquaintances of random nodes (individuals). The strategy requires no
knowledge of the node degrees or any other global knowledge, as do targeted
immunization strategies. We study analytically the critical threshold for
complete immunization. We also study the strategy with respect to the
susceptible-infected-removed epidemiological model. We show that the
immunization threshold is dramatically reduced with the suggested strategy, for
all studied cases.Comment: Revtex, 5 pages, 4 ps fig
You are only as safe as your riskiest contact: Effective Covid-19 vaccine distribution using local network information
When vaccines are limited, prior research has suggested it is most protective to distribute vaccines to the most central individuals – those who are most likely to spread the disease. But surveying the population’s social network is a costly and time-consuming endeavour, often not completed before vaccination must begin. This paper validates a local targeting method for distributing vaccines. That is, ask randomly chosen individuals to nominate for vaccination the person they are in contact with who has the most disease-spreading contacts. Even better, ask that person to nominate the next person for vaccination, and so on. To validate this approach, we simulate the spread of COVID-19 along empirical contact networks collected in two high schools, in the United States and France, pre-COVID. These weighted networks are built by recording whenever students are in close spatial proximity and facing one another. We show here that nomination of most popular contacts performs significantly better than random vaccination, and on par with strategies which assume a full survey of the population. These results are robust over a range of realistic disease-spread parameters, as well as a larger synthetic contact network of 3000 individuals
Decentralization in Bitcoin and Ethereum Networks
Blockchain-based cryptocurrencies have demonstrated how to securely implement
traditionally centralized systems, such as currencies, in a decentralized
fashion. However, there have been few measurement studies on the level of
decentralization they achieve in practice. We present a measurement study on
various decentralization metrics of two of the leading cryptocurrencies with
the largest market capitalization and user base, Bitcoin and Ethereum. We
investigate the extent of decentralization by measuring the network resources
of nodes and the interconnection among them, the protocol requirements
affecting the operation of nodes, and the robustness of the two systems against
attacks. In particular, we adapted existing internet measurement techniques and
used the Falcon Relay Network as a novel measurement tool to obtain our data.
We discovered that neither Bitcoin nor Ethereum has strictly better properties
than the other. We also provide concrete suggestions for improving both
systems.Comment: Financial Cryptography and Data Security 201
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