3,535 research outputs found
Coupling of cytoplasm and adhesion dynamics determines cell polarization and locomotion
Observations of single epidermal cells on flat adhesive substrates have
revealed two distinct morphological and functional states, namely a
non-migrating symmetric unpolarized state and a migrating asymmetric polarized
state. These states are characterized by different spatial distributions and
dynamics of important biochemical cell components: F-actin and myosin-II form
the contractile part of the cytoskeleton, and integrin receptors in the plasma
membrane connect F-actin filaments to the substratum. In this way, focal
adhesion complexes are assembled, which determine cytoskeletal force
transduction and subsequent cell locomotion. So far, physical models have
reduced this phenomenon either to gradients in regulatory control molecules or
to different mechanics of the actin filament system in different regions of the
cell.
Here we offer an alternative and self-organizational model incorporating
polymerization, pushing and sliding of filaments, as well as formation of
adhesion sites and their force dependent kinetics. All these phenomena can be
combined into a non-linearly coupled system of hyperbolic, parabolic and
elliptic differential equations. Aim of this article is to show how relatively
simple relations for the small-scale mechanics and kinetics of participating
molecules may reproduce the emergent behavior of polarization and migration on
the large-scale cell level.Comment: v2 (updates from proof): add TOC, clarify Fig. 4, fix several typo
Generating analyzers with PAG
To produce high qualitiy code, modern compilers use global optimization algorithms based on it abstract interpretation. These algorithms are rather complex; their implementation is therfore a non-trivial task and error-prone. However, since thez are based on a common theory, they have large similar parts. We conclude that analyzer writing better should be replaced with analyzer generation. We present the tool sf PAG that has a high level functional input language to specify data flow analyses. It offers th specifications of even recursive data structures and is therfore not limited to bit vector problems. sf PAG generates efficient analyzers wich can be easily integrated in existing compilers. The analyzers are interprocedural, they can handle recursive procedures with local variables and higher order functions. sf PAG has successfully been tested by generating several analyzers (e.g. alias analysis, constant propagation, inerval analysis) for an industrial quality ANSI-C and Fortran90 compiler. This technical report consits of two parts; the first introduces the generation system and the second evaluates generated analyzers with respect to their space and time consumption. bf Keywords: data flow analysis, specification and generation of analyzers, lattice specification, abstract syntax specification, interprocedural analysis, compiler construction
Design Options for Service Directories in Business Networks
Web services and service oriented architectures (SOA) are spreading in many organizations toachieve business interoperability of their intra- and inter-organizational business processes. SOA isbased on the idea that service providers develop and publish web services via standardized interfacesin directories (registries) where the services will be found and bound by service consumers. Whilethese registry structures have emerged into a standard for local SOA implementations, the questionremains how service directories should be organized in a business network, i.e. when multiple companieswith individual SOA solutions interact. This research develops a framework for the analysis ofservice directories in business networks and provides design options for combining separate and distributedservice directories. These design options are based on the range, reach, and richness of webservice markets in the business network. The framework is applied to two business network cases
Single atoms in a standing-wave dipole trap
We trap a single cesium atom in a standing-wave optical dipole trap. Special
experimental procedures, designed to work with single atoms, are used to
measure the oscillation frequency and the atomic energy distribution in the
dipole trap. These methods rely on unambiguously detecting presence or loss of
the atom using its resonance fluorescence in the magneto-optical trap.Comment: 8 pages, 7 figures, submitted to Phys. Rev.
EyeScout: Active Eye Tracking for Position and Movement Independent Gaze Interaction with Large Public Displays
While gaze holds a lot of promise for hands-free interaction with public displays, remote eye trackers with their confined tracking box restrict users to a single stationary position in front of the display. We present EyeScout, an active eye tracking system that combines an eye tracker mounted on a rail system with a computational method to automatically detect and align the tracker with the user's lateral movement. EyeScout addresses key limitations of current gaze-enabled large public displays by offering two novel gaze-interaction modes for a single user: In "Walk then Interact" the user can walk up to an arbitrary position in front of the display and interact, while in "Walk and Interact" the user can interact even while on the move. We report on a user study that shows that EyeScout is well perceived by users, extends a public display's sweet spot into a sweet line, and reduces gaze interaction kick-off time to 3.5 seconds -- a 62% improvement over state of the art solutions. We discuss sample applications that demonstrate how EyeScout can enable position and movement-independent gaze interaction with large public displays
An optical conveyor belt for single neutral atoms
Using optical dipole forces we have realized controlled transport of a single
or any desired small number of neutral atoms over a distance of a centimeter
with sub-micrometer precision. A standing wave dipole trap is loaded with a
prescribed number of cesium atoms from a magneto-optical trap. Mutual detuning
of the counter-propagating laser beams moves the interference pattern, allowing
us to accelerate and stop the atoms at preselected points along the standing
wave. The transportation efficiency is close to 100%. This optical "single-atom
conveyor belt" represents a versatile tool for future experiments requiring
deterministic delivery of a prescribed number of atoms on demand.Comment: 8 pages, 8 figures, submitted to Applied Physics
Cache behavior prediction by abstract interpretation
Abstract interpretation is a technique for the static detection of dynamic properties of programs. It is semantics based, that is, it computes approximative properties of the semantics of programs. On this basis, it allows for correctness proofs of analyses. It replaces commonly used ad hoc techniques by systematic, provable ones, and it allows the automatic generation of analyzers from specifications as in the Program Analyzer Generator, PAG. In this paper, abstract interpretation is applied to the problem of predicting the cache behavior of programs. Abstract semantics of machine programs are defined which determine the contents of caches. For interprocedural analysis, existing methods are examined and a new approach that is especially tailored for the cache analysis is presented. This allows for a static classification of the cache behavior of memory references of programs. The calculated information can be used to sharpen worst case execution time estimations. It is possible to analyze instruction, data, and combined instruction/data caches for common (re)placement and write strategies. Experimental results are presented that demonstrate the applicability of the analysis
Generalized Voronoi Tessellation as a Model of Two-dimensional Cell Tissue Dynamics
Voronoi tessellations have been used to model the geometric arrangement of
cells in morphogenetic or cancerous tissues, however so far only with flat
hypersurfaces as cell-cell contact borders. In order to reproduce the
experimentally observed piecewise spherical boundary shapes, we develop a
consistent theoretical framework of multiplicatively weighted distance
functions, defining generalized finite Voronoi neighborhoods around cell bodies
of varying radius, which serve as heterogeneous generators of the resulting
model tissue. The interactions between cells are represented by adhesive and
repelling force densities on the cell contact borders. In addition, protrusive
locomotion forces are implemented along the cell boundaries at the tissue
margin, and stochastic perturbations allow for non-deterministic motility
effects. Simulations of the emerging system of stochastic differential
equations for position and velocity of cell centers show the feasibility of
this Voronoi method generating realistic cell shapes. In the limiting case of a
single cell pair in brief contact, the dynamical nonlinear Ornstein-Uhlenbeck
process is analytically investigated. In general, topologically distinct tissue
conformations are observed, exhibiting stability on different time scales, and
tissue coherence is quantified by suitable characteristics. Finally, an
argument is derived pointing to a tradeoff in natural tissues between cell size
heterogeneity and the extension of cellular lamellae.Comment: v1: 34 pages, 19 figures v2: reformatted 43 pages, 21 figures, 1
table; minor clarifications, extended supplementary materia
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