138,996 research outputs found
On reducing the complexity of matrix clocks
Matrix clocks are a generalization of the notion of vector clocks that allows
the local representation of causal precedence to reach into an asynchronous
distributed computation's past with depth , where is an integer.
Maintaining matrix clocks correctly in a system of nodes requires that
everymessage be accompanied by numbers, which reflects an exponential
dependency of the complexity of matrix clocks upon the desired depth . We
introduce a novel type of matrix clock, one that requires only numbers to
be attached to each message while maintaining what for many applications may be
the most significant portion of the information that the original matrix clock
carries. In order to illustrate the new clock's applicability, we demonstrate
its use in the monitoring of certain resource-sharing computations
On the stability of spacelike hypersurfaces
In this paper we study the strong stability of spacelike hypersurfaces with
constant -th mean curvature in Generalized Robertson-Walker spacetimes of
constant sectional curvature. In particular, we treat the case in which the
ambient spacetime is the de Sitter space
On the phase transitions of graph coloring and independent sets
We study combinatorial indicators related to the characteristic phase
transitions associated with coloring a graph optimally and finding a maximum
independent set. In particular, we investigate the role of the acyclic
orientations of the graph in the hardness of finding the graph's chromatic
number and independence number. We provide empirical evidence that, along a
sequence of increasingly denser random graphs, the fraction of acyclic
orientations that are `shortest' peaks when the chromatic number increases, and
that such maxima tend to coincide with locally easiest instances of the
problem. Similar evidence is provided concerning the `widest' acyclic
orientations and the independence number
Quantum density anomaly in optically trapped ultracold gases
We show that the Bose-Hubbard Model exhibits an increase in density with
temperature at fixed pressure in the regular fluid regime and in the superfluid
phase. The anomaly at the Bose-Einstein condensate is the first density anomaly
observed in a quantum state. We propose that the mechanism underlying both the
normal phase and the superfluid phase anomalies is related to zero point
entropies and ground state phase transitions. A connection with the typical
experimental scales and setups is also addressed. This key finding opens a new
pathway for theoretical and experimental studies of water-like anomalies in the
area of ultracold quantum gases
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