Publications

Barone, Matthew F.; Miller, Nathan M.; Davis, Warren L.; Fike, Jeffrey A.

Abstract not provided.

Barone, Matthew F.; Miller, Nathan M.; Davis, Warren L.; Fike, Jeffrey A.

Abstract not provided.

Miller, Nathan M.; Barone, Matthew F.; Davis, Warren L.; Fike, Jeffrey A.

Abstract not provided.

AIAA Aviation 2019 Forum

Miller, Nathan M.; Barone, Matthew F.; Davis, Warren L.; Fike, Jeffrey A.

Near-wall turbulence models in Large-Eddy Simulation (LES) typically approximate near-wall behavior using a solution to the mean flow equations. This approach inevitably leads to errors when the modeled flow does not satisfy the assumptions surrounding the use of a mean flow approximation for an unsteady boundary condition. Herein, modern machine learning (ML) techniques are utilized to implement a coordinate frame invariant model of the wall shear stress that is derived specifically for complex flows for which mean near-wall models are known to fail. The model operates on a set of scalar and vector invariants based on data taken from the first LES grid point off the wall. Neural networks were trained and validated on spatially filtered direct numerical simulation (DNS) data. The trained networks were then tested on data to which they were never previously exposed and comparisons of the accuracy of the networks’ predictions of wall-shear stress were made to both a standard mean wall model approach and to the true stress values taken from the DNS data. The ML approach showed considerable improvement in both the accuracy of individual shear stress predictions as well as produced a more accurate distribution of wall shear stress values than did the standard mean wall model. This result held both in regions where the standard mean approach typically performs satisfactorily as well as in regions where it is known to fail, and also in cases where the networks were trained and tested on data taken from the same flow type/region as well as when trained and tested on data from different respective flow topologies.

Barone, Matthew F.; Fike, Jeffrey A.; Chowdhary, Kamaljit S.; Davis, Warren L.; Ling, Julia L.; Martin, Shawn

Abstract not provided.

Barone, Matthew F.; Fike, Jeffrey A.; Chowdhary, Kamaljit S.; Davis, Warren L.; Ling, Julia L.; Martin, Shawn

Abstract not provided.

wilson, andrew w.; Wade, Daniel W.; Ling, Julia L.; Chowdhary, Kamaljit S.; Davis, Warren L.; Barone, Matthew F.; Barone, Matthew F.; Fike, Jeffrey A.

Abstract not provided.

Kalashnikova, Irina; Barone, Matthew F.; Fike, Jeffrey A.; Balajewicz, Maciej B.; Arunajatesan, Srinivasan A.; van Bloemen Waanders, Bart G.; Dowell, Earl D.

Abstract not provided.

Barone, Matthew F.; Ling, Julia L.; Davis, Warren L.; Chowdhary, Kamaljit S.; Fike, Jeffrey A.

Abstract not provided.

AIAA SciTech Forum - 55th AIAA Aerospace Sciences Meeting

Ling, Julia L.; Barone, Matthew F.; Davis, Warren L.; Chowdhary, K.; Fike, Jeffrey A.

In many aerospace applications, it is critical to be able to model fluid-structure interactions. In particular, correctly predicting the power spectral density of pressure fluctuations at surfaces can be important for assessing potential resonances and failure modes. Current turbulence modeling methods, such as wall-modeled Large Eddy Simulation and Detached Eddy Simulation, cannot reliably predict these pressure fluctuations for many applications of interest. The focus of this paper is on efforts to use data-driven machine learning methods to learn correction terms for the wall pressure fluctuation spectrum. In particular, the non-locality of the wall pressure fluctuations in a compressible boundary layer is investigated using random forests and neural networks trained and evaluated on Direct Numerical Simulation data.

Ling, Julia L.; Barone, Matthew F.; Davis, Warren L.; Chowdhary, Kamaljit S.; Fike, Jeffrey A.

Abstract not provided.

Spotz, William S.; Kalashnikova, Irina; Bosler, Peter A.; Fike, Jeffrey A.; Guba, Oksana G.; Smith, Thomas M.; Watkins, Jerry E.; Demeshko, Irina P.

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Bosler, Peter A.; Bova, S.W.; Demeshko, Irina P.; Fike, Jeffrey A.; Guba, Oksana G.; Overfelt, James R.; Roesler, Erika L.; Salinger, Andrew G.; Smith, Thomas M.; Kalashnikova, Irina; Watkins, Jerry E.

The Next Generation Global Atmosphere Model LDRD project developed a suite of atmosphere models: a shallow water model, an x - z hydrostatic model, and a 3D hydrostatic model, by using Albany, a finite element code. Albany provides access to a large suite of leading-edge Sandia high- performance computing technologies enabled by Trilinos, Dakota, and Sierra. The next-generation capabilities most relevant to a global atmosphere model are performance portability and embedded uncertainty quantification (UQ). Performance portability is the capability for a single code base to run efficiently on diverse set of advanced computing architectures, such as multi-core threading or GPUs. Embedded UQ refers to simulation algorithms that have been modified to aid in the quantifying of uncertainties. In our case, this means running multiple samples for an ensemble concurrently, and reaping certain performance benefits. We demonstrate the effectiveness of these approaches here as a prelude to introducing them into ACME.

Spotz, William S.; Fike, Jeffrey A.; Kalashnikova, Irina; Salinger, Andrew G.; Phipps, Eric T.

Abstract not provided.

Spotz, William S.; Trucano, Timothy G.; Fike, Jeffrey A.

Abstract not provided.

Spotz, William S.; Spotz, William S.; Fike, Jeffrey A.; Fike, Jeffrey A.; Kalashnikova, Irina; Kalashnikova, Irina; Salinger, Andrew G.; Salinger, Andrew G.; Bova, S.W.; Bova, S.W.; Overfelt, James R.; Overfelt, James R.; Taylor, Mark A.; Taylor, Mark A.; Phipps, Eric T.; Phipps, Eric T.

Abstract not provided.

Spotz, William S.; Demeshko, Irina D.; Smith, Thomas M.; Fike, Jeffrey A.

Abstract not provided.

Kalashnikova, Irina; van Bloemen Waanders, Bart G.; Arunajatesan, Srinivasan A.; Barone, Matthew F.; Fike, Jeffrey A.

Abstract not provided.

Kalashnikova, Irina; Barone, Matthew F.; Fike, Jeffrey A.; Arunajatesan, Srinivasan A.; van Bloemen Waanders, Bart G.

Abstract not provided.

Kalashnikova, Irina; Arunajatesan, Srinivasan A.; Barone, Matthew F.; van Bloemen Waanders, Bart G.; Fike, Jeffrey A.

This report describes work performed from June 2012 through May 2014 as a part of a Sandia Early Career Laboratory Directed Research and Development (LDRD) project led by the first author. The objective of the project is to investigate methods for building stable and efficient proper orthogonal decomposition (POD)/Galerkin reduced order models (ROMs): models derived from a sequence of high-fidelity simulations but having a much lower computational cost. Since they are, by construction, small and fast, ROMs can enable real-time simulations of complex systems for onthe- spot analysis, control and decision-making in the presence of uncertainty. Of particular interest to Sandia is the use of ROMs for the quantification of the compressible captive-carry environment, simulated for the design and qualification of nuclear weapons systems. It is an unfortunate reality that many ROM techniques are computationally intractable or lack an a priori stability guarantee for compressible flows. For this reason, this LDRD project focuses on the development of techniques for building provably stable projection-based ROMs. Model reduction approaches based on continuous as well as discrete projection are considered. In the first part of this report, an approach for building energy-stable Galerkin ROMs for linear hyperbolic or incompletely parabolic systems of partial differential equations (PDEs) using continuous projection is developed. The key idea is to apply a transformation induced by the Lyapunov function for the system, and to build the ROM in the transformed variables. It is shown that, for many PDE systems including the linearized compressible Euler and linearized compressible Navier-Stokes equations, the desired transformation is induced by a special inner product, termed the “symmetry inner product”. Attention is then turned to nonlinear conservation laws. A new transformation and corresponding energy-based inner product for the full nonlinear compressible Navier-Stokes equations is derived, and it is demonstrated that if a Galerkin ROM is constructed in this inner product, the ROM system energy will be bounded in a way that is consistent with the behavior of the exact solution to these PDEs, i.e., the ROM will be energy-stable. The viability of the linear as well as nonlinear continuous projection model reduction approaches developed as a part of this project is evaluated on several test cases, including the cavity configuration of interest in the targeted application area. In the second part of this report, some POD/Galerkin approaches for building stable ROMs using discrete projection are explored. It is shown that, for generic linear time-invariant (LTI) systems, a discrete counterpart of the continuous symmetry inner product is a weighted L2 inner product obtained by solving a Lyapunov equation. This inner product was first proposed by Rowley et al., and is termed herein the “Lyapunov inner product“. Comparisons between the symmetry inner product and the Lyapunov inner product are made, and the performance of ROMs constructed using these inner products is evaluated on several benchmark test cases. Also in the second part of this report, a new ROM stabilization approach, termed “ROM stabilization via optimization-based eigenvalue reassignment“, is developed for generic LTI systems. At the heart of this method is a constrained nonlinear least-squares optimization problem that is formulated and solved numerically to ensure accuracy of the stabilized ROM. Numerical studies reveal that the optimization problem is computationally inexpensive to solve, and that the new stabilization approach delivers ROMs that are stable as well as accurate. Summaries of “lessons learned“ and perspectives for future work motivated by this LDRD project are provided at the end of each of the two main chapters.