Your search keyword '"Tretiak, Dima"' showing total 5 results

1. Physics-Constrained Generative Adversarial Networks for 3D Turbulence

Author

Tretiak, Dima, Mohan, Arvind T., and Livescu, Daniel

Subjects

Physics - Computational Physics, Computer Science - Machine Learning

Abstract

Generative Adversarial Networks (GANs) have received wide acclaim among the machine learning (ML) community for their ability to generate realistic 2D images. ML is being applied more often to complex problems beyond those of computer vision. However, current frameworks often serve as black boxes and lack physics embeddings, leading to poor ability in enforcing constraints and unreliable models. In this work, we develop physics embeddings that can be stringently imposed, referred to as hard constraints, in the neural network architecture. We demonstrate their capability for 3D turbulence by embedding them in GANs, particularly to enforce the mass conservation constraint in incompressible fluid turbulence. In doing so, we also explore and contrast the effects of other methods of imposing physics constraints within the GANs framework, especially penalty-based physics constraints popular in literature. By using physics-informed diagnostics and statistics, we evaluate the strengths and weaknesses of our approach and demonstrate its feasibility.

Published

2022

2. The ISTI Rapid Response on Exploring Cloud Computing 2018

Author

Coffrin, Carleton, Arnold, James, Eidenbenz, Stephan, Aberle, Derek, Ambrosiano, John, Baker, Zachary, Brambilla, Sara, Brown, Michael, Carter, K. Nolan, Chu, Pinghan, Conry, Patrick, Costigan, Keeley, Eberhardt, Ariane, Fobes, David M., Gausmann, Adam, Harris, Sean, Heimer, Donovan, Holmes, Marlin, Junor, Bill, Kiss, Csaba, Linger, Steve, Linn, Rodman, Lo, Li-Ta, MacCarthy, Jonathan, Marcillo, Omar, McGinnis, Clay, McQuarters, Alexander, Michalak, Eric, Mohan, Arvind, Nelson, Matt, Oyen, Diane, Parikh, Nidhi, Pasqualini, Donatella, Pope, Aaron s., Porter, Reid, Rawlings, Chris, Reinbolt, Hannah, Rivenburgh, Reid, Romero, Phil, Schoonover, Kevin, Skurikhin, Alexei, Tauritz, Daniel, Tretiak, Dima, Wang, Zhehui, Wernicke, James, Wolfe, Brad, Wolfram, Phillip, and Woodring, Jonathan

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Machine Learning

Abstract

This report describes eighteen projects that explored how commercial cloud computing services can be utilized for scientific computation at national laboratories. These demonstrations ranged from deploying proprietary software in a cloud environment to leveraging established cloud-based analytics workflows for processing scientific datasets. By and large, the projects were successful and collectively they suggest that cloud computing can be a valuable computational resource for scientific computation at national laboratories.

Published

2019

3. Development of a Machine Learning Wall Model for Large-Eddy Simulation of Gas Turbine Film Cooling Flows

Author

Kumar, Tadbhagya, primary, Pal, Pinaki, additional, Wu, Sicong, additional, Nunno, A. Cody, additional, Owoyele, Opeoluwa, additional, Joly, Michael, additional, and Tretiak, Dima, additional

Published

2023

4. Spatio-temporal deep learning models of 3D turbulence with physics informed diagnostics

Author

Mohan, Arvind T., primary, Tretiak, Dima, additional, Chertkov, Misha, additional, and Livescu, Daniel, additional

Published

2020

5. Assessment of Machine Learning Wall Modeling Approaches for Large Eddy Simulation of Gas Turbine Film Cooling Flows: An a Priori Study.

Author

Kumar, Tadbhagya, Pal, Pinaki, Sicong Wu, Nunno, A. Cody, Owoyele, Opeoluwa, Joly, Michael M., and Tretiak, Dima

Abstract

In this work, a priori analysis of machine learning (ML) strategies is carried out with the goal of data-driven wall modeling for large eddy simulation (LES) of gas turbine film cooling flows. High-fidelity flow datasets are extracted from wall-resolved LES (WRLES) of flow over a flat plate interacting with the coolant flow supplied by a single row of 7-7-7 shaped cooling holes inclined at 30 degrees with the flat plate at different blowing ratios (BR). The WRLES are performed using the high-order Nek5000 spectral element computational fluid dynamics (CFD) solver. Light gradient boosting machine (LightGBM) is employed as the ML algorithm for the data-driven wall model. Parametric tests are conducted to systematically assess the influence of a wide range of input flow features (velocity components, velocity gradients, pressure gradients, and fluid properties) on the accuracy of ML wall model with respect to prediction of wall shear stress. In addition, the use of spatial stencil and time delay is also explored within the ML wall modeling framework. It is shown that features associated with gradients of the streamwise and spanwise velocity components have a major impact on the prediction fidelity of wall model, while the effect of gradients of wall-normal velocity component is found to be negligible. Moreover, adding flow feature information from an x-y-z spatial stencil significantly improves the ML model accuracy and generalizability compared to just using local flow features from the matching location. Overall, highest prediction accuracy is achieved when both spatial stencil and time delay features are incorporated within the data-driven wall modeling paradigm. [ABSTRACT FROM AUTHOR]

Published

2024