jofre_domino_iaccarino2018
Summary
A framework for characterizing structural uncertainty in large-eddy simulation closures. L. Jofre, S.P. Domino and G. Iaccarino. Flow, Turbulence and Combustion, 100(2):341-363, 2018. (URL)
Abstract
Motivated by the sizable increase of available computing resources, large-eddy simulation of complex turbulent flow is becoming increasingly popular. The underlying filtering operation of this approach enables to represent only large-scale motions. However, the small-scale fluctuations and their effects on the resolved flow field require additional modeling. As a consequence, the assumptions made in the closure formulations become potential sources of incertitude that can impact the quantities of interest. The objective of this work is to introduce a framework for the systematic estimation of structural uncertainty in large-eddy simulation closures. In particular, the methodology proposed is independent of the initial model form, computationally efficient, and suitable to general flow solvers. The approach is based on introducing controlled perturbations to the turbulent stress tensor in terms of magnitude, shape and orientation, such that propagation of their effects can be assessed. The framework is rigorously described, and physically plausible bounds for the perturbations are proposed. As a means to test its performance, a comprehensive set of numerical experiments are reported for which physical interpretation of the deviations in the quantities of interest are discussed.
Bibtex entry
@ARTICLE { jofre_domino_iaccarino2018,
TITLE = { A framework for characterizing structural uncertainty in large-eddy simulation closures },
AUTHOR = { L. Jofre and S.P. Domino and G. Iaccarino },
JOURNAL = { Flow, Turbulence and Combustion },
VOLUME = { 100 },
NUMBER = { 2 },
PAGES = { 341--363 },
YEAR = { 2018 },
ABSTRACT = { Motivated by the sizable increase of available computing resources, large-eddy simulation of complex turbulent flow is becoming increasingly popular. The underlying filtering operation of this approach enables to represent only large-scale motions. However, the small-scale fluctuations and their effects on the resolved flow field require additional modeling. As a consequence, the assumptions made in the closure formulations become potential sources of incertitude that can impact the quantities of interest. The objective of this work is to introduce a framework for the systematic estimation of structural uncertainty in large-eddy simulation closures. In particular, the methodology proposed is independent of the initial model form, computationally efficient, and suitable to general flow solvers. The approach is based on introducing controlled perturbations to the turbulent stress tensor in terms of magnitude, shape and orientation, such that propagation of their effects can be assessed. The framework is rigorously described, and physically plausible bounds for the perturbations are proposed. As a means to test its performance, a comprehensive set of numerical experiments are reported for which physical interpretation of the deviations in the quantities of interest are discussed. },
URL = { https://doi.org/10.1007/s10494-017-9844-8 },
}