2,386 research outputs found
A Quantitative Study of Java Software Buildability
Researchers, students and practitioners often encounter a situation when the
build process of a third-party software system fails. In this paper, we aim to
confirm this observation present mainly as anecdotal evidence so far. Using a
virtual environment simulating a programmer's one, we try to fully
automatically build target archives from the source code of over 7,200 open
source Java projects. We found that more than 38% of builds ended in failure.
Build log analysis reveals the largest portion of errors are
dependency-related. We also conduct an association study of factors affecting
build success
Time management displays for shuttle countdown
The Intelligent Launch Decision Support System project is developing a Time Management System (TMS) for the NASA Test Director (NTD) to use for time management during Shuttle terminal countdown. TMS is being developed in three phases: an information phase; a tool phase; and an advisor phase. The information phase is an integrated display (TMID) of firing room clocks, of graphic timelines with Ground Launch Sequencer events, and of constraints. The tool phase is a what-if spreadsheet (TMWI) for devising plans for resuming from unplanned hold situations. It is tied to information in TMID, propagates constraints forward and backward to complete unspecified values, and checks the plan against constraints. The advisor phase is a situation advisor (TMSA), which proactively suggests tactics. A concept prototype for TMSA is under development. The TMID is currently undergoing field testing. Displays for TMID and TMWI are described. Descriptions include organization, rationale for organization, implementation choices and constraints, and use by NTD
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Deck the Walls with Anisotropic Colloids in Nematic Liquid Crystals.
Nematic liquid crystals (NLCs) offer remarkable opportunities to direct colloids to form complex structures. The elastic energy field that dictates colloid interactions is determined by the NLC director field, which is sensitive to and can be controlled by boundaries including vessel walls and colloid surfaces. By molding the director field via liquid-crystal alignment on these surfaces, elastic energy landscapes can be defined to drive structure formation. We focus on colloids in otherwise defect-free director fields formed near undulating walls. Colloids can be driven along prescribed paths and directed to well-defined docking sites on such wavy boundaries. Colloids that impose strong alignment generate topologically required companion defects. Configurations for homeotropic colloids include a dipolar structure formed by the colloid and its companion hedgehog defect or a quadrupolar structure formed by the colloid and its companion Saturn ring. Adjacent to wavy walls with wavelengths larger than the colloid diameter, spherical particles are attracted to locations along the wall with distortions in the nematic director field that complement those from the colloid. This is the basis of lock-and-key interactions. Here, we study ellipsoidal colloids with homeotropic anchoring near complex undulating walls. The walls impose distortions that decay with distance from the wall to a uniform director in the far field. Ellipsoids form dipolar defect configurations with the colloid's major axis aligned with the far field director. Two distinct quadrupolar defect structures also form, stabilized by confinement; these include the Saturn I configuration with the ellipsoid's major axis aligned with the far field director and the Saturn II configuration with the major axis perpendicular to the far field director. The ellipsoid orientation varies only weakly in bulk and near undulating walls. All configurations are attracted to walls with long, shallow waves. However, for walls with wavelengths that are small compared to the colloid length, Saturn II is repelled, allowing selective docking of aligned objects. Deep, narrow wells prompt the insertion of a vertical ellipsoid. By introducing an opening at the bottom of such a deep well, we study colloids within pores that connect two domains. Ellipsoids with different aspect ratios find different equilibrium positions. An ellipsoid of the right dimension and aspect ratio can plug the pore, creating a class of 2D selective membranes
Linking partial and quasi dynamical symmetries in rotational nuclei
Background: Quasi dynamical symmetries (QDS) and partial dynamical symmetries
(PDS) play an important role in the understanding of complex systems. Up to now
these symmetry concepts have been considered to be unrelated. Purpose:
Establish a link between PDS and QDS and find an emperical manifestation.
Methods: Quantum number fluctuations and the intrinsic state formalism are used
within the framework of the interacting boson model of nuclei. Results: A
previously unrecognized region of the parameter space of the interacting boson
model that has both O(6) PDS (purity) and SU(3) QDS (coherence) in the ground
band is established. Many rare-earth nuclei approximately satisfying both
symmetry requirements are identified. Conclusions: PDS are more abundant than
previously recognized and can lead to a QDS of an incompatible symmetry.Comment: 5 pages, 4 figures, 1 tabl
Evolution of populations expanding on curved surfaces
The expansion of a population into new habitat is a transient process that
leaves its footprints in the genetic composition of the expanding population.
How the structure of the environment shapes the population front and the
evolutionary dynamics during such a range expansion is little understood. Here,
we investigate the evolutionary dynamics of populations consisting of many
selectively neutral genotypes expanding on curved surfaces. Using a combination
of individual-based off-lattice simulations, geometrical arguments, and
lattice-based stepping-stone simulations, we characterise the effect of
individual bumps on an otherwise flat surface. Compared to the case of a range
expansion on a flat surface, we observe a transient relative increase, followed
by a decrease, in neutral genetic diversity at the population front. In
addition, we find that individuals at the sides of the bump have a dramatically
increased expected number of descendants, while their neighbours closer to the
bump's centre are far less lucky. Both observations can be explained using an
analytical description of straight paths (geodesics) on the curved surface.
Complementing previous studies of heterogeneous flat environments, the findings
here build our understanding of how complex environments shape the evolutionary
dynamics of expanding populations.Comment: This preprint has also been posted to http://www.biorxiv.org with
doi: 10.1101/406280. Seven pages with 5 figures, plus an appendix containing
3 pages with 1 figur
Lassoing saddle splay and the geometrical control of topological defects
Systems with holes, such as colloidal handlebodies and toroidal droplets,
have been studied in the nematic liquid crystal (NLC) 4-cyano-4'-pentylbiphenyl
(5CB): both point and ring topological defects can occur within each hole and
around the system, while conserving the system's overall topological charge.
However, what has not been fully appreciated is the ability to manipulate the
hole geometry with homeotropic (perpendicular) anchoring conditions to induce
complex, saddle-like deformations. We exploit this by creating an array of
holes suspended in an NLC cell with oriented planar (parallel) anchoring at the
cell boundaries. We study both 5CB and a binary mixture of bicyclohexane
derivatives (CCN-47 and CCN-55). Through simulations and experiments, we study
how the bulk saddle deformations of each hole interact to create novel defect
structures, including an array of disclination lines, reminiscent of those
found in liquid crystal blue phases. The line locations are tunable via the NLC
elastic constants, the cell geometry, and the size and spacing of holes in the
array. This research lays the groundwork for the control of complex elastic
deformations of varying length scales via geometrical cues in materials that
are renowned in the display industry for their stability and easy
manipulability.Comment: 9 pages, 7 figures, 1 supplementary figur
Assessment of regional myocardial blood flow and regional fractional oxygen extraction in dogs, using 15O-water and 15O-hemoglobin
A new approach to the assessment of regional myocardial blood flow and fractional oxygen extraction has been developed using 15O-water (H2- 15O) and 15O-hemoglobin (15O-Hb). Bolus doses (1 mCi) of H2-15O and 15O- Hb were injected 10 minutes apart into the left main coronary artery of 12 normal dogs. Sequential images of regional myocardial tracer clearance were obtained over 5 minutes with a positron camera. Myocardial blood flow calculated from the monoexponential washout of H2- 15O after background correction was 78 +/- 6 (SE) ml/100 g per min. Functional images of regional blood flow in which the image of peak activity was divided by the integrated image of H2-15O washout were derived by computer processing. These images demonstrated homogeneous blood flow in the normal myocardium. Fractional myocardial O2 extraction was determined from an image of initial distribution of O2 used (obtained by extrapolating back to time zero the series of images obtained after 15O-Hb administration), divided by initial distribution of O2 delivered (obtained by back extrapolating H2-15O washout). These functional images showed uniform distribution of fractional O2 extraction in the normal myocardium. Thus, these studies show that regional myocardial blood flow and regional oxygen extraction can be measured simultaneously by sequential imaging after serial intracoronary injections of H2-15O and 15O-Hb
Elasticity-Dependent Self-assembly of Micro-Templated Chromonic Liquid Crystal Films
We explore micropatterned director structures of aqueous lyotropic chromonic
liquid crystal (LCLC) films created on square lattice cylindrical-micropost
substrates. The structures are manipulated by modulating the LCLC mesophases
and their elastic properties via concentration through drying. Nematic LCLC
films exhibit preferred bistable alignment along the diagonals of the micropost
lattice. Columnar LCLC films, dried from nematics, form two distinct director
and defect configurations: a diagonally aligned director pattern with local
squares of defects, and an off-diagonal configuration with zig-zag defects. The
formation of these states appears to be tied to the relative splay and bend
free energy costs of the initial nematic films. The observed nematic and
columnar configurations are understood numerically using a Landau-de Gennes
free energy model. Among other attributes, the work provide first examples of
quasi-2D micropatterning of LC films in the columnar phase and lyotropic LC
films in general, and it demonstrates alignment and configuration switching of
typically difficult-to-align LCLC films via bulk elastic properties.Comment: 9 pages; 9 figures; accepted for publication in Soft Matte
Elastocapillary driven assembly of particles at free-standing smectic-A films
Colloidal particles at complex fluid interfaces and within films assemble to
form ordered structures with high degrees of symmetry via interactions that
include capillarity, elasticity, and other fields like electrostatic charge.
Here we study microparticle interactions within free-standing smectic-A films,
in which the elasticity arising from the director field distortion and
capillary interactions arising from interface deformation compete to direct the
assembly of motile particles. New colloidal assemblies and patterns, ranging
from 1D chains to 2D aggregates, sensitive to the initial wetting conditions of
particles at the smectic film, are reported. This work paves the way to
exploiting LC interfaces as a means to direct spontaneously formed,
reconfigurable, and optically active materials.Comment: 8 pages, 6 figures. Supplementary Materials: 3 pages, 3 figure
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