Your search keyword '"D. Heinemann"' showing total 2 results

1. Short term fluctuations of wind and solar power systems

Author

M Anvari, G Lohmann, M Wächter, P Milan, E Lorenz, D Heinemann, M Reza Rahimi Tabar, and Joachim Peinke

Subjects

renewable energies, intermittency, jumpy and diffusive dynamics, tipping point, time-delayed feedback method, 05.45.Tp, Science, Physics, QC1-999

Abstract

Wind and solar power are known to be highly influenced by weather events and may ramp up or down abruptly. Such events in the power production influence not only the availability of energy, but also the stability of the entire power grid. By analysing significant amounts of data from several regions around the world with resolutions of seconds to minutes, we provide strong evidence that renewable wind and solar sources exhibit multiple types of variability and nonlinearity in the time scale of seconds and characterise their stochastic properties. In contrast to previous findings, we show that only the jumpy characteristic of renewable sources decreases when increasing the spatial size over which the renewable energies are harvested. Otherwise, the strong non-Gaussian, intermittent behaviour in the cumulative power of the total field survives even for a country-wide distribution of the systems. The strong fluctuating behaviour of renewable wind and solar sources can be well characterised by Kolmogorov-like power spectra and q -exponential probability density functions. Using the estimated potential shape of power time series, we quantify the jumpy or diffusive dynamic of the power. Finally we propose a time delayed feedback technique as a control algorithm to suppress the observed short term non-Gaussian statistics in spatially strong correlated and intermittent renewable sources.

Published

2016

2. Kohn-Sham density functionals accurately solved by a finite-element multi-grid (FEM-MG) method for lighter atoms and diatomic molecules

Author

A v Kopylow, D Heinemann, and D. Kolb

Subjects

Physics, Multi grid, Kohn–Sham equations, Atomic physics, Condensed Matter Physics, Axial symmetry, Stability (probability), Scaling, Diatomic molecule, Atomic and Molecular Physics, and Optics, Finite element method, Computational physics, Sparse matrix

Abstract

The finite-element multi-grid method combines the stability and high accuracy of FEM with the ability of MG to solve sparse matrix equations very quickly, scaling basically linear with the number of unknowns. It is applied to effectively two-dimensional problems like atoms and diatomic molecules under axial symmetry described by density and orbital functionals, respectively. The high solution efficiency (accuracy and speed) of FEM-MG obtained already is demonstrated for which in many respects is a particularly difficult case. Thus our finite-element multi-grid method allows large-scale investigations with controlled accuracy of various combinations of exchange-correlation density functionals for the description of lighter atoms and diatomic molecules.

Published

1998