43 research outputs found
Bose-Einstein condensation dynamics from the numerical solution of the Gross-Pitaevskii equation
We study certain stationary and time-evolution problems of trapped
Bose-Einstein condensates using the numerical solution of the Gross-Pitaevskii
equation with both spherical and axial symmetries. We consider time-evolution
problems initiated by changing the interatomic scattering length or harmonic
trapping potential suddenly in a stationary condensate. These changes introduce
oscillations in the condensate which are studied in detail. We use a time
iterative split-step method for the solution of the time-dependent
Gross-Pitaevskii equation, where all nonlinear and linear nonderivative terms
are treated separately from the time propagation with the kinetic energy terms.
Even for an arbitrarily strong nonlinear term this leads to extremely accurate
and stable results after millions of time iterations of the original equation.Comment: LaTeX2e (iop style files included), 17 pages, 6 EPS figures, accepted
for publication in J. Phys. B: At. Mol. Opt. Phy
Time series analysis for minority game simulations of financial markets
The minority game (MG) model introduced recently provides promising insights
into the understanding of the evolution of prices, indices and rates in the
financial markets. In this paper we perform a time series analysis of the model
employing tools from statistics, dynamical systems theory and stochastic
processes. Using benchmark systems and a financial index for comparison,
several conclusions are obtained about the generating mechanism for this kind
of evolut ion. The motion is deterministic, driven by occasional random
external perturbation. When the interval between two successive perturbations
is sufficiently large, one can find low dimensional chaos in this regime.
However, the full motion of the MG model is found to be similar to that of the
first differences of the SP500 index: stochastic, nonlinear and (unit root)
stationary.Comment: LaTeX 2e (elsart), 17 pages, 3 EPS figures and 2 tables, accepted for
publication in Physica
Analytical calculation of the transition to complete phase synchronization in coupled oscillators
Here we present a system of coupled phase oscillators with nearest neighbors
coupling, which we study for different boundary conditions. We concentrate at
the transition to total synchronization. We are able to develop exact solutions
for the value of the coupling parameter when the system becomes completely
synchronized, for the case of periodic boundary conditions as well as for an
open chain with fixed ends. We compare the results with those calculated
numerically.Comment: 5 pages, 3 figure
Characteristic features of the Shannon information entropy of dipolar Bose-Einstein condensates
Calculation of the Shannon information entropy (S) and its connection with the order-disorder transition and with inter-particle interaction provide a challenging research area in the field of quantum information. Experimental progress with cold trapped atoms has corroborated this interest. In the present work, S is calculated for the Bose-Einstein condensate (BEC) with dominant dipolar interaction for different dipole strengths, trap aspect ratios, and number of particles (N). Trapped dipolar bosons in an anisotropic trap provide an example of a system where the effective interaction is strongly determined by the trap geometry. The main conclusion of the present calculation is that the anisotropic trap reduces the number of degrees of freedom, resulting in more ordered configurations. Landsberg's order parameter exhibits quick saturation with the increase in scattering length in both prolate and oblate traps. We also define the threshold scattering length which makes the system completely disordered. Unlike non-dipolar BEC in a spherical trap, we do not find a universal linear relation between S and lnN, and we, therefore, introduce a general quintic polynomial fit rather well working for a wide range of particle numbers