5,200 research outputs found
Some comments on the inverse problem of pure point diffraction
In a recent paper, Lenz and Moody (arXiv:1111.3617) presented a method for
constructing families of real solutions to the inverse problem for a given pure
point diffraction measure. Applying their technique and discussing some
possible extensions, we present, in a non-technical manner, some examples of
homometric structures.Comment: 6 pages, contribution to Aperiodic 201
Experimental investigation of transitional flow in a toroidal pipe
The flow instability and further transition to turbulence in a toroidal pipe
(torus) with curvature (tube-to-coiling diameter) 0.049 is investigated
experimentally. The flow inside the toroidal pipe is driven by a steel sphere
fitted to the inner pipe diameter. The sphere is moved with constant azimuthal
velocity from outside the torus by a moving magnet. The experiment is designed
to investigate curved pipe flow by optical measurement techniques. Using
stereoscopic particle image velocimetry, laser Doppler velocimetry and pressure
drop measurements, the flow is measured for Reynolds numbers ranging from 1000
to 15000. Time- and space-resolved velocity fields are obtained and analysed.
The steady axisymmetric basic flow is strongly influenced by centrifugal
effects. On an increase of the Reynolds number we find a sequence of
bifurcations. For Re=4075 a supercritical bifurcation to an oscillatory flow is
found in which waves travel in the streamwise direction with a phase velocity
slightly faster than the mean flow. The oscillatory flow is superseded by a
presumably quasi-periodic flow at a further increase of the Reynolds number
before turbulence sets in. The results are found to be compatible, in general,
with earlier experimental and numerical investigations on transition to
turbulence in helical and curved pipes. However, important aspects of the
bifurcation scenario differ considerably
Exceeding the asymptotic limit of polymer drag reduction
The drag of turbulent flows can be drastically decreased by addition of small
amounts of high molecular weight polymers. While drag reduction initially
increases with polymer concentration, it eventually saturates to what is known
as the maximum drag reduction (MDR) asymptote; this asymptote is generally
attributed to the dynamics being reduced to a marginal yet persistent state of
subdued turbulent motion. Contrary to this accepted view we will show in the
following that for an appropriate choice of parameters polymers can reduce the
drag beyond the suggested asymptotic limit, eliminating turbulence and giving
way to laminar flow. However at higher polymer concentrations the laminar state
becomes unstable, resulting in a fluctuating flow with the characteristic drag
of the MDR asymptote. The asymptotic state is hence dynamically disconnected
from ordinary turbulence.Comment: 6 pages, 6 figure
Dynamics of viscoelastic pipe flow in the maximum drag reduction limit
Polymer additives can substantially reduce the drag of turbulent flows and
the upper limit, the so called "maximum drag reduction" (MDR) asymptote is
universal, i.e. independent of the type of polymer and solvent used. Until
recently, the consensus was that, in this limit, flows are in a marginal state
where only a minimal level of turbulence activity persists. Observations in
direct numerical simulations using minimal sized channels appeared to support
this view and reported long "hibernation" periods where turbulence is
marginalized. In simulations of pipe flow we find that, indeed, with increasing
Weissenberg number (Wi), turbulence expresses long periods of hibernation if
the domain size is small. However, with increasing pipe length, the temporal
hibernation continuously alters to spatio-temporal intermittency and here the
flow consists of turbulent puffs surrounded by laminar flow. Moreover, upon an
increase in Wi, the flow fully relaminarises, in agreement with recent
experiments. At even larger Wi, a different instability is encountered causing
a drag increase towards MDR. Our findings hence link earlier minimal flow unit
simulations with recent experiments and confirm that the addition of polymers
initially suppresses Newtonian turbulence and leads to a reverse transition.
The MDR state on the other hand results from a separate instability and the
underlying dynamics corresponds to the recently proposed state of
elasto-inertial-turbulence (EIT).Comment: 18 pages, 5 figure
How to Mix Molecules with Mathematics
In this paper we develop two methods to calculate thermodynamic properties of mixtures. Starting point are the basic assumptions that also form the basis for the COSMO-RS model. In this approach, the individual molecules are represented by their geometrical shape with an electrical charge density on their surfaces. Next, the surface is split up into surface segments each with its own charge. In COSMO-RS a strong reduction is introduced by treating the segments as if they are completely independent. In the present study we take into account that the coupling between two patches is essentially dependent on the charge distribution on neighboring segments and on the local geometrical structure of the surface. Two approaches are followed. The first one points out how the model
equations, which comprise the optimization of the entropy and conservation of internal energy, can efficiently be solved in general, thus also if the dependency between segments and the local geometry is included in the expression for the coupling energy between segments. In the second method the configuration with maximal entropy and prescribed energy is sought via simulation. Successive molecular configurations of the mixture are simulated and updated via a genetic algorithm to optimize the entropy. The second method is more time consuming but very general
Data-driven and Model-based Verification: a Bayesian Identification Approach
This work develops a measurement-driven and model-based formal verification
approach, applicable to systems with partly unknown dynamics. We provide a
principled method, grounded on reachability analysis and on Bayesian inference,
to compute the confidence that a physical system driven by external inputs and
accessed under noisy measurements, verifies a temporal logic property. A case
study is discussed, where we investigate the bounded- and unbounded-time safety
of a partly unknown linear time invariant system
Forbidden induced subgraphs and the price of connectivity for feedback vertex set.
Let fvs(G) and cfvs(G) denote the cardinalities of a minimum feedback vertex set and a minimum connected feedback vertex set of a graph G, respectively. For a graph class G, the price of connectivity for feedback vertex set (poc-fvs) for G is defined as the maximum ratio cfvs(G)/fvs(G) over all connected graphs G in G. It is known that the poc-fvs for general graphs is unbounded. We study the poc-fvs for graph classes defined by a finite family H of forbidden induced subgraphs. We characterize exactly those finite families H for which the poc-fvs for H-free graphs is bounded by a constant. Prior to our work, such a result was only known for the case where |H|=1
Observer-based correct-by-design controller synthesis
Current state-of-the-art correct-by-design controllers are designed for
full-state measurable systems. This work first extends the applicability of
correct-by-design controllers to partially observable LTI systems. Leveraging
2nd order bounds we give a design method that has a quantifiable robustness to
probabilistic disturbances on state transitions and on output measurements. In
a case study from smart buildings we evaluate the new output-based
correct-by-design controller on a physical system with limited sensor
information
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