55,866 research outputs found
Nonlinear Young integrals via fractional calculus
For H\"older continuous functions and , we define
nonlinear integral via fractional calculus. This
nonlinear integral arises naturally in the Feynman-Kac formula for stochastic
heat equations with random coefficients. We also define iterated nonlinear
integrals.Comment: arXiv admin note: substantial text overlap with arXiv:1404.758
Penta-hepta defect chaos in a model for rotating hexagonal convection
In a model for rotating non-Boussinesq convection with mean flow we identify
a regime of spatio-temporal chaos that is based on a hexagonal planform and is
sustained by the {\it induced nucleation} of dislocations by penta-hepta
defects. The probability distribution function for the number of defects
deviates substantially from the usually observed Poisson-type distribution. It
implies strong correlations between the defects inthe form of density-dependent
creation and annihilation rates of defects. We extract these rates from the
distribution function and also directly from the defect dynamics.Comment: 4 pages, 5 figures, submitted to PR
Rattling and freezing in a 1-D transport model
We consider a heat conduction model introduced in \cite{Collet-Eckmann 2009}.
This is an open system in which particles exchange momentum with a row of
(fixed) scatterers. We assume simplified bath conditions throughout, and give a
qualitative description of the dynamics extrapolating from the case of a single
particle for which we have a fairly clear understanding. The main phenomenon
discussed is {\it freezing}, or the slowing down of particles with time. As
particle number is conserved, this means fewer collisions per unit time, and
less contact with the baths; in other words, the conductor becomes less
effective. Careful numerical documentation of freezing is provided, and a
theoretical explanation is proposed. Freezing being an extremely slow process,
however, the system behaves as though it is in a steady state for long
durations. Quantities such as energy and fluxes are studied, and are found to
have curious relationships with particle density
On the miscible Rayleigh-Taylor instability: two and three dimensions
We investigate the miscible Rayleigh-Taylor (RT) instability in both 2 and 3
dimensions using direct numerical simulations, where the working fluid is
assumed incompressible under the Boussinesq approximation. We first consider
the case of randomly perturbed interfaces. With a variety of diagnostics, we
develop a physical picture for the detailed temporal development of the mixed
layer: We identify three distinct evolutionary phases in the development of the
mixed layer, which can be related to detailed variations in the growth of the
mixing zone. Our analysis provides an explanation for the observed differences
between two and three-dimensional RT instability; the analysis also leads us to
concentrate on the RT models which (1) work equally well for both laminar and
turbulent flows, and (2) do not depend on turbulent scaling within the mixing
layer between fluids. These candidate RT models are based on point sources
within bubbles (or plumes) and interaction with each other (or the background
flow). With this motivation, we examine the evolution of single plumes, and
relate our numerical results (of single plumes) to a simple analytical model
for plume evolution.Comment: 31 pages, 27 figures, to appear in November issue of JFM, 2001. For
better figures: http://astro.uchicago.edu/~young/ps/jfmtry08.ps.
Studies of human dynamic space orientation using techniques of control theory
Three-dimensional contact analog display system development for use in surface, subsurface, air, and space vehicle
Studies of human dynamic space orientation using techniques of control theory Status report, Jun. 1967 - Jun. 1968
Human dynamic space orientation using techniques of control theor
- …