3,589 research outputs found
Realistic Simulation of Local Solar Supergranulation
I represent results three-dimensional numerical simulation of solar surface
convection on scales local supergranulation with realistic model physics. I
study thermal structure of convective motions in photosphere, the range of
convection cell sizes and the penetration depths of convection. A portion of
the solar photosphere extending 100 x 100 Mm horizontally and from 0 Mm down to
20 Mm below the visible surface is considered. I take equation of state and
opacities of stellar matter and distribution with radius of all physical
variables from Solar Standard Model. The equations of fully compressible
radiation hydrodynamics with dynamical viscosity and gravity are solved. The
high order conservative PPML difference scheme for the hydrodynamics, the
method of characteristic for the radiative transfer and dynamical viscosity
from subgrid scale modeling are applied. The simulations are conducted on a
uniform horizontal grid of 1000 x 1000, with 168 nonuniformly spaced vertical
grid points, on 256 processors with distributed memory multiprocessors on
supercomputer MVS5000 in Computational Centre of Russian Academy of Sciences.Comment: 4 pages, 3 figures. To appear in AIP Conference Proceedings,
"Exploring the Solar System and the Universe", Apr 8-12 2008, Bucharest,
Romania, eds. Vasile Mioc, Cristiana Dumitrache & Nedelia A. Popesc
Extension of the sun-synchronous Orbit
Through careful consideration of the orbit perturbation force due to the oblate nature of the primary body a secular variation of the ascending node angle of a near-polar orbit can be induced without expulsion of propellant. Resultantly, the orbit perturbations can be used to maintain the orbit plane in, for example, a near-perpendicular (or at any other angle) alignment to the Sun-line throughout the full year of the primary body; such orbits are normally termed Sun-synchronous orbits [1, 2]. Sun-synchronous orbits about the Earth are typically near-circular Low-Earth Orbits (LEOs), with an altitude of less than 1500 km. It is normal to design a LEO such that the orbit period is synchronised with the rotation of the Earth‟s surface over a given period, such that a repeating ground-track is established. A repeating ground-track, together with the near-constant illumination conditions of the ground-track when observed from a Sun-synchronous orbit, enables repeat observations of a target over an extended period under similar illumination conditions [1, 2]. For this reason, Sun-synchronous orbits are extensively used by Earth Observation (EO) platforms, including currently the Environmental Satellite (ENVISAT), the second European Remote Sensing satellite (ERS-2) and many more. By definition, a given Sun-synchronous orbit is a finite resource similar to a geostationary orbit. A typical characterising parameter of a Sun-synchronous orbit is the Mean Local Solar Time (MLST) at descending node, with a value of 1030 hours typical. Note that ERS-1 and ERS-2 used a MLST at descending node of 1030 hours ± 5 minutes, while ENVISAT uses a 1000 hours ± 5 minutes MLST at descending node [3]. Following selection of the MLST at descending node and for a given desired repeat ground-track, the orbit period and hence the semi-major axis are fixed, thereafter assuming a circular orbit is desired it is found that only a single orbit inclination will enable a Sun-synchronous orbit [2]. As such, only a few spacecraft can populate a given repeat ground-track Sun-synchronous orbit without compromise, for example on the MLST at descending node. Indeed a notable feature of on-going studies by the ENVISAT Post launch Support Office is the desire to ensure sufficient propellant remains at end-of-mission for re-orbiting to a graveyard orbit to ensure the orbital slot is available for future missions [4]. An extension to the Sun-synchronous orbit is considered using an undefined, non-orientation constrained, low-thrust propulsion system. Initially the low-thrust propulsion system will be considered for the free selection of orbit inclination and altitude while maintaining the Sun-synchronous condition. Subsequently the maintenance of a given Sun-synchronous repeat-ground track will be considered, using the low-thrust propulsion system to enable the free selection of orbit altitude. An analytical expression will be developed to describe these extensions prior to then validating the analytical expressions within a numerical simulation of a spacecraft orbit. Finally, an analysis will be presented on transfer and injection trajectories to these orbits
MEASURING PERFORMANCE, VALUE CREATION AND VALUE-BASED MANAGEMENT IN THE CONTEXT OF COMPETITIVENESS AND GLOBALIZATION
In times of uncertainty, knowing the best methods of measuring performance and creating value, determines the increase competitiveness of companies. By development of international markets and globalization, companies pursue entry in many national, regional or international markets. Competitiveness of companies is linked to performance; the latter can be presented by various methods, as this company must have a sustainable presence on the market. Performance and value creation concepts are common in company reports, but most often these concepts are not defined. Through this study, we highlight their importance and we measure this direct link between past performance and future value creation.performance; value creation; value-based management; competitiveness.
Successive Coordinate Search and Component-by-Component Construction of Rank-1 Lattice Rules
The (fast) component-by-component (CBC) algorithm is an efficient tool for
the construction of generating vectors for quasi-Monte Carlo rank-1 lattice
rules in weighted reproducing kernel Hilbert spaces. We consider product
weights, which assigns a weight to each dimension. These weights encode the
effect a certain variable (or a group of variables by the product of the
individual weights) has. Smaller weights indicate less importance. Kuo (2003)
proved that the CBC algorithm achieves the optimal rate of convergence in the
respective function spaces, but this does not imply the algorithm will find the
generating vector with the smallest worst-case error. In fact it does not. We
investigate a generalization of the component-by-component construction that
allows for a general successive coordinate search (SCS), based on an initial
generating vector, and with the aim of getting closer to the smallest
worst-case error. The proposed method admits the same type of worst-case error
bounds as the CBC algorithm, independent of the choice of the initial vector.
Under the same summability conditions on the weights as in [Kuo,2003] the error
bound of the algorithm can be made independent of the dimension and we
achieve the same optimal order of convergence for the function spaces from
[Kuo,2003]. Moreover, a fast version of our method, based on the fast CBC
algorithm by Nuyens and Cools, is available, reducing the computational cost of
the algorithm to operations, where denotes the number
of function evaluations. Numerical experiments seeded by a Korobov-type
generating vector show that the new SCS algorithm will find better choices than
the CBC algorithm and the effect is better when the weights decay slower.Comment: 13 pages, 1 figure, MCQMC2016 conference (Stanford
A folding inhibitor of the HIV-1 Protease
Being the HIV-1 Protease (HIV-1-PR) an essential enzyme in the viral life
cycle, its inhibition can control AIDS. The folding of single domain proteins,
like each of the monomers forming the HIV-1-PR homodimer, is controlled by
local elementary structures (LES, folding units stabilized by strongly
interacting, highly conserved, as a rule hydrophobic, amino acids). These LES
have evolved over myriad of generations to recognize and strongly attract each
other, so as to make the protein fold fast and be stable in its native
conformation. Consequently, peptides displaying a sequence identical to those
segments of the monomers associated with LES are expected to act as competitive
inhibitors and thus destabilize the native structure of the enzyme. These
inhibitors are unlikely to lead to escape mutants as they bind to the protease
monomers through highly conserved amino acids which play an essential role in
the folding process. The properties of one of the most promising inhibitors of
the folding of the HIV-1-PR monomers found among these peptides is demonstrated
with the help of spectrophotometric assays and CD spectroscopy
Multi-agent collaborative search : an agent-based memetic multi-objective optimization algorithm applied to space trajectory design
This article presents an algorithm for multi-objective optimization that blends together a number of heuristics. A population of agents combines heuristics that aim at exploring the search space both globally and in a neighbourhood of each agent. These heuristics are complemented with a combination of a local and global archive. The novel agent-based algorithm is tested at first on a set of standard problems and then on three specific problems in space trajectory design. Its performance is compared against a number of state-of-the-art multi-objective optimization algorithms that use the Pareto dominance as selection criterion: non-dominated sorting genetic algorithm (NSGA-II), Pareto archived evolution strategy (PAES), multiple objective particle swarm optimization (MOPSO), and multiple trajectory search (MTS). The results demonstrate that the agent-based search can identify parts of the Pareto set that the other algorithms were not able to capture. Furthermore, convergence is statistically better although the variance of the results is in some cases higher
Computing the set of Epsilon-efficient solutions in multiobjective space mission design
In this work, we consider multiobjective space mission design problems. We will start from the need, from a practical point of view, to consider in addition to the (Pareto) optimal solutions also nearly optimal ones. In fact, extending the set of solutions for a given mission to those nearly optimal significantly increases the number of options for the decision maker and gives a measure of the size of the launch windows corresponding to each optimal solution, i.e., a measure of its robustness. Whereas the possible loss of such approximate solutions compared to optimal—and possibly even ‘better’—ones is dispensable. For this, we will examine several typical problems in space trajectory design—a biimpulsive transfer from the Earth to the asteroid Apophis and two low-thrust multigravity assist transfers—and demonstrate the possible benefit of the novel approach. Further, we will present a multiobjective evolutionary algorithm which is designed for this purpose
Constraints on the near-Earth asteroid obliquity distribution from the Yarkovsky effect
Aims. From lightcurve and radar data we know the spin axis of only 43 near-Earth asteroids. In this paper we attempt to constrain the spin axis obliquity distribution of near-Earth asteroids by leveraging the Yarkovsky effect and its dependence on an asteroid’s obliquity.
Methods. By modeling the physical parameters driving the Yarkovsky effect, we solve an inverse problem where we test different simple parametric obliquity distributions. Each distribution results in a predicted Yarkovsky effect distribution that we compare with a X2 test to a dataset of 125 Yarkovsky estimates.
Results. We find different obliquity distributions that are statistically satisfactory. In particular, among the considered models, the best-fit solution is a quadratic function, which only depends on two parameters, favors extreme obliquities, consistent with the expected outcomes from the YORP effect, has a 2:1 ratio between retrograde and direct rotators, which is in agreement with theoretical predictions, and is statistically consistent with the distribution of known spin axes of near-Earth asteroids
Time-dependent Maxwell field operators and field energy density for an atom near a conducting wall
We consider the time evolution of the electric and magnetic field operators
for a two-level atom, interacting with the electromagnetic field, placed near
an infinite perfectly conducting wall. We solve iteratively the Heisenberg
equations for the field operators and obtain the electric and magnetic energy
density operators around the atom (valid for any initial state). Then we
explicitly evaluate them for an initial state with the atom in its bare ground
state and the field in the vacuum state. We show that the results can be
physically interpreted as the superposition of the fields propagating directly
from the atom and the fields reflected on the wall. Relativistic causality in
the field propagation is discussed. Finally we apply these results to the
calculation of the dynamical Casimir-Polder interaction energy in the far zone
between two atoms when a boundary condition such as a conducting wall is
present. Magnetic contributions to the interatomic Casimir-Polder interaction
in the presence of the wall are also considered. We show that, in the limit of
large times, the known results of the stationary case are recovered.Comment: 11 page
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