Your search keyword '"Schmittfull, M."' showing total 2 results

1. Fast estimation of gravitational and primordial bispectra in large scale structures.

Author

Schmittfull, M. M., Regan, D. M., and Shellard, E. P. S.

Subjects

*ESTIMATION theory, *GRAVITATIONAL fields, *COST effectiveness, *SPECTRUM analysis, *DARK matter, *COMPARATIVE studies

Abstract

We present the implementation of a fast estimator for the full dark matter bispectrum of a three-dimensional (3D) particle distribution relying on a separable modal expansion of the bispectrum. The computational cost of accurate bispectrum estimation is negligible relative to simulation evolution, so the isotropic bispectrum can be used as a standard diagnostic whenever the power spectrum is evaluated. As an application, we measure the evolution of gravitational and primordial dark matter bispectra in N-body simulations with Gaussian and non-Gaussian initial conditions of the local, equilateral, orthogo-nal and flattened shape. The results are compared to theoretical models using a 3D visualization, 3D shape correlations and the cumulative bispectrum signal-to-noise, all of which can be evaluated extremely quickly. Our measured bispectra are determined by 0(50) coefficients, which can be used as fitting formulas in the nonlinear regime and for non-Gaussian initial conditions. In the nonlinear regime with k < 2h???-1, we find an excellent correlation between the measured dark matter bispectrum and a simple model based on a "constant" bispectrum plus a (nonlinear) tree-level gravitational bispectrum. In the same range for non-Gaussian simulations, we find the measured excess bispectrum (i.e. the difference with the measured gravitational bispectrum) has an excellent correlation with a phenomenological model consisting of the constant bispectrum plus a (nonlinear) tree-level primordial bispectrum. We demonstrate that the constant contribution to the non-Gaussian bispectrum can be understood as a time-shift of the constant mode in the gravitational bispectrum, which is motivated by the one-halo model. The final amplitude of this extra non-Gaussian constant contribution is directly related to the initial amplitude of the constant mode in the primordial bispectrum. We also comment on the effects of regular grid and glass initial conditions on the bispectrum. [ABSTRACT FROM AUTHOR]

Published

2013

2. Fast estimation of gravitational and primordial bispectra in large scale structures.

Author

Schmittfull, M. M., Regan, D. M., and Shellard, E. P. S.

Subjects

*DARK matter, *POWER spectra, *GRAVITATION

Abstract

We present the implementation of a fast estimator for the full dark matter bispectrum of a three-dimensional (3D) particle distribution relying on a separable modal expansion of the bispectrum. The computational cost of accurate bispectrum estimation is negligible relative to simulation evolution, so the isotropic bispectrum can be used as a standard diagnostic whenever the power spectrum is evaluated. As an application, we measure the evolution of gravitational and primordial dark matter bispectra in N-body simulations with Gaussian and non-Gaussian initial conditions of the local, equilateral, orthogonal and flattened shape. The results are compared to theoretical models using a 3D visualization, 3D shape correlations and the cumulative bispectrum signal-to-noise, all of which can be evaluated extremely quickly. Our measured bispectra are determined by O(50) coefficients, which can be used as fitting formulas in the nonlinear regime and for non-Gaussian initial conditions. In the nonlinear regime with k < 2h Mpc-1, we find an excellent correlation between the measured dark matter bispectrum and a simple model based on a "constant" bispectrum plus a (nonlinear) tree-level gravitational bispectrum. In the same range for non-Gaussian simulations, we find the measured excess bispectrum (i.e. the difference with the measured gravitational bispectrum) has an excellent correlation with a phenomenological model consisting of the constant bispectrum plus a (nonlinear) tree-level primordial bispectrum. We demonstrate that the constant contribution to the non-Gaussian bispectrum can be understood as a time-shift of the constant mode in the gravitational bispectrum, which is motivated by the one-halo model. The final amplitude of this extra non-Gaussian constant contribution is directly related to the initial amplitude of the constant mode in the primordial bispectrum. We also comment on the effects of regular grid and glass initial conditions on the bispectrum. [ABSTRACT FROM AUTHOR]

Published

2013