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

1. Coupling kinetic and continuum using data-driven maximum entropy distribution.

Author

Sadr, Mohsen, Wang, Qian, and Gorji, M. Hossein

Subjects

*MAXIMUM entropy method, *ENTROPY, *SHOCK tubes, *FISHER information, *BLENDED learning, *ALGORITHMS

Abstract

• Applying machine learning (ANN/GP) on closure problem by maximum entropy ansatz. • Recovering bi-modal density using data-driven maximum entropy distribution. • Leveraging machine learning for hybrid kinetic-continuum particle solver. • Validating data-driven NSF-Boltzmann solver for Sod's shock tube. • Achieving accurate, efficient, and robust hybrid particle solver. An important class of multi-scale flow scenarios deals with an interplay between kinetic and continuum phenomena. While hybrid solvers provide a natural way to cope with these settings, two issues restrict their performance. Foremost, the inverse problem implied by estimating distributions has to be addressed, to provide boundary conditions for the kinetic solver. The next issue comes from defining a robust yet accurate switching criterion between the two solvers. This study introduces a data-driven kinetic-continuum coupling, where the Maximum-Entropy-Distribution (MED) is employed to parametrize distributions arising from continuum field variables. Two regression methodologies of Gaussian-Processes (GPs) and Artificial-Neural-Networks (ANNs) are utilized to predict MEDs efficiently. Hence the MED estimates are employed to carry out the coupling, besides providing a switching criterion. To achieve the latter, a continuum breakdown parameter is defined by means of the Fisher information distance computed from the MED estimates. We test the performance of our devised MED estimators by recovering bi-modal densities. Next, MED estimates are integrated into a hybrid kinetic-continuum solution algorithm. Here Direct Simulation Monte-Carlo (DSMC) and Smoothed-Particle Hydrodynamics (SPH) are chosen as kinetic and continuum solvers, respectively. The problem of monatomic gas inside Sod's shock tube is investigated, where DSMC-SPH coupling is realized by applying the devised MED estimates. Very good agreements with respect to benchmark solutions along with a promising speed-up are observed in our reported test cases. [ABSTRACT FROM AUTHOR]

Published

2021

2. Gaussian Process Regression for Maximum Entropy Distribution.

Author

Sadr, Mohsen, Torrilhon, Manuel, and Gorji, M. Hossein

Subjects

*KRIGING, *RADIAL basis functions, *ENTROPY, *LAGRANGE multiplier, *KERNEL functions, *MAXIMUM entropy method

Abstract

• Devising Bayesian inference for fast evaluation of maximum entropy distribution. • Adopting Radial basis function for covariance kernel. • Excellent recovery of bi-modal densities among others. Maximum-Entropy Distributions offer an attractive family of probability densities suitable for moment closure problems. Yet finding the Lagrange multipliers which parametrize these distributions, turns out to be a computational bottleneck for practical closure settings. Motivated by recent success of Gaussian processes, we investigate the suitability of Gaussian priors to approximate the Lagrange multipliers as a map of a given set of moments. Examining various kernel functions, the hyperparameters are optimized by maximizing the log-likelihood. The performance of the devised data-driven Maximum-Entropy closure is studied for couple of test cases including relaxation of non-equilibrium distributions governed by Bhatnagar-Gross-Krook and Boltzmann kinetic equations. [ABSTRACT FROM AUTHOR]

Published

2020