1,175 research outputs found
Fast Structuring of Radio Networks for Multi-Message Communications
We introduce collision free layerings as a powerful way to structure radio
networks. These layerings can replace hard-to-compute BFS-trees in many
contexts while having an efficient randomized distributed construction. We
demonstrate their versatility by using them to provide near optimal distributed
algorithms for several multi-message communication primitives.
Designing efficient communication primitives for radio networks has a rich
history that began 25 years ago when Bar-Yehuda et al. introduced fast
randomized algorithms for broadcasting and for constructing BFS-trees. Their
BFS-tree construction time was rounds, where is the network
diameter and is the number of nodes. Since then, the complexity of a
broadcast has been resolved to be rounds. On the other hand, BFS-trees have been used as a crucial building
block for many communication primitives and their construction time remained a
bottleneck for these primitives.
We introduce collision free layerings that can be used in place of BFS-trees
and we give a randomized construction of these layerings that runs in nearly
broadcast time, that is, w.h.p. in rounds for any constant . We then use these
layerings to obtain: (1) A randomized algorithm for gathering messages
running w.h.p. in rounds. (2) A randomized -message
broadcast algorithm running w.h.p. in rounds. These
algorithms are optimal up to the small difference in the additive
poly-logarithmic term between and . Moreover, they imply the
first optimal round randomized gossip algorithm
Filaments from the galaxy distribution and from the velocity field in the local universe
The cosmic web that characterizes the large-scale structure of the Universe
can be quantified by a variety of methods. For example, large redshift surveys
can be used in combination with point process algorithms to extract long
curvilinear filaments in the galaxy distribution. Alternatively, given a full
3D reconstruction of the velocity field, kinematic techniques can be used to
decompose the web into voids, sheets, filaments and knots. In this paper we
look at how two such algorithms - the Bisous model and the velocity shear web -
compare with each other in the local Universe (within 100 Mpc), finding good
agreement. This is both remarkable and comforting, given that the two methods
are radically different in ideology and applied to completely independent and
different data sets. Unsurprisingly, the methods are in better agreement when
applied to unbiased and complete data sets, like cosmological simulations, than
when applied to observational samples. We conclude that more observational data
is needed to improve on these methods, but that both methods are most likely
properly tracing the underlying distribution of matter in the Universe.Comment: 6 Pages, 2 figures, Submitted to MNRAS Letter
Ending the License to Exploit: Administrative Oversight of Consumer Contracts
Current approaches to consumer standard form contracts generally assume that aggrieved consumers can adequately detect and challenge exploitative terms and that vigilant courts can effectively scrutinize them. Some even believe that market forces and reputational constraints can deter firms from incorporating exploitative terms into their form contracts or dissuade them from actually relying on such terms. Criticizing these assumptions, this Article calls for a conceptual shift toward the problem of exploitative consumer contracts. This Article suggests supplementing the current means of addressing exploitation in consumer contracts with a dynamic preventive model of administrative oversight. Specifically, this Article proposes a professional system of public supervision over the content of consumer form contracts. This Article demonstrates how such a mechanism, if shrewdly designed, can cost-effectively tackle the widespread use of unfair, unconscionable, or legally invalid terms. Although not a panacea, the proposed regulatory regime has the promise of shifting the main burden of tackling exploitative boilerplate from the currently feeble and ineffective system of private enforcement to a sophisticated and robust scheme of administrative scrutiny
Interferences in the density of two Bose-Einstein condensates consisting of identical or different atoms
The density of two {\it initially independent} condensates which are allowed
to expand and overlap can show interferences as a function of time due to
interparticle interaction. Two situations are separately discussed and
compared: (1) all atoms are identical and (2) each condensate consists of a
different kind of atoms. Illustrative examples are presented.Comment: 12 pages, 3 figure
A kinematic classification of the cosmic web
A new approach for the classification of the cosmic web is presented. In
extension of the previous work of Hahn et al. (2007) and Forero-Romero et al.
(2009) the new algorithm is based on the analysis of the velocity shear tensor
rather than the gravitational tidal tensor. The procedure consists of the
construction of the the shear tensor at each (grid) point in space and the
evaluation of its three eigenvectors. A given point is classified to be either
a void, sheet, filament or a knot according to the number of eigenvalues above
a certain threshold, 0, 1, 2, or 3 respectively. The threshold is treated as a
free parameter that defines the web. The algorithm has been applied to a dark
matter only, high resolution simulation of a box of side-length 64Mpc
and N = particles with the framework of the WMAP5/LCDM model. The
resulting velocity based cosmic web resolves structures down to <0.1Mpc
scales, as opposed to the ~1Mpc scale of the tidal based web. The
under-dense regions are made of extended voids bisected by planar sheets, whose
density is also below the mean. The over-dense regions are vastly dominated by
the linear filaments and knots. The resolution achieved by the velocity based
cosmic web provides a platform for studying the formation of halos and galaxies
within the framework of the cosmic web.Comment: 8 pages, 4 Figures, MNRAS Accepted 2012 June 19. Received 2012 May
10; in original form 2011 August 2
Planes of satellite galaxies and the cosmic web
Recent observational studies have demonstrated that the majority of satellite
galaxies tend to orbit their hosts on highly flattened, vast, possibly
co-rotating planes. Two nearly parallel planes of satellites have been
confirmed around the M31 galaxy and around the Centaurus A galaxy, while the
Milky Way also sports a plane of satellites. It has been argued that such an
alignment of satellites on vast planes is unexpected in the standard
({\Lambda}CDM) model of cosmology if not even in contradiction to its generic
predictions. Guided by {\Lambda}CDM numerical simulations, which suggest that
satellites are channeled towards hosts along the axis of the slowest collapse
as dictated by the ambient velocity shear tensor, we re-examine the planes of
local satellites systems within the framework of the local shear tensor derived
from the Cosmicflows-2 dataset. The analysis reveals that the Local Group and
Centaurus A reside in a filament stretched by the Virgo cluster and compressed
by the expansion of the Local Void. Four out of five thin planes of satellite
galaxies are indeed closely aligned with the axis of compression induced by the
Local Void. Being the less massive system, the moderate misalignment of the
Milky Way's satellite plane can likely be ascribed to its greater
susceptibility to tidal torques, as suggested by numerical simulations. The
alignment of satellite systems in the local universe with the ambient shear
field is thus in general agreement with predictions of the {\Lambda}CDM model.Comment: 9 pages, 3 figures, 3 tables. Accepted by MNRAS, 9 June 201
Detection of arbitrarily large dynamic ground motions with a dense high-rate GPS network
We describe the detection of teleseismic surface waves from the 3 November 2002 Mw 7.9 Denali fault earthquake in Alaska with a dense network of 1 Hz GPS stations in southern California, about 3900 km from the event. Relative horizontal displacements with amplitudes in excess of 15 mm and duration of 700 seconds agree with integrated velocities recorded by nearby broadband seismometers with an rms difference of 2â3 mm. The displacements are derived from independent 1 Hz instantaneous positions demonstrating that a GPS network can provide direct measurements of arbitrarily large dynamic and static ground horizontal displacements at periods longer than 1 s and amplitudes above 2 mm, with an inherent precision (signal to noise) that improves indefinitely with amplitude without clipping and in real time. Highârate, realâtime GPS networks can enhance earthquake detection and seismic risk mitigation and support other applications such as intelligent transportation and civil infrastructure monitoring
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