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Separable Physics-informed Neural Networks for Solving the BGK Model of the Boltzmann Equation (2403.06342v1)

Published 10 Mar 2024 in math.NA, cs.LG, and cs.NA

Abstract: In this study, we introduce a method based on Separable Physics-Informed Neural Networks (SPINNs) for effectively solving the BGK model of the Boltzmann equation. While the mesh-free nature of PINNs offers significant advantages in handling high-dimensional partial differential equations (PDEs), challenges arise when applying quadrature rules for accurate integral evaluation in the BGK operator, which can compromise the mesh-free benefit and increase computational costs. To address this, we leverage the canonical polyadic decomposition structure of SPINNs and the linear nature of moment calculation, achieving a substantial reduction in computational expense for quadrature rule application. The multi-scale nature of the particle density function poses difficulties in precisely approximating macroscopic moments using neural networks. To improve SPINN training, we introduce the integration of Gaussian functions into SPINNs, coupled with a relative loss approach. This modification enables SPINNs to decay as rapidly as Maxwellian distributions, thereby enhancing the accuracy of macroscopic moment approximations. The relative loss design further ensures that both large and small-scale features are effectively captured by the SPINNs. The efficacy of our approach is demonstrated through a series of five numerical experiments, including the solution to a challenging 3D Riemann problem. These results highlight the potential of our novel method in efficiently and accurately addressing complex challenges in computational physics.

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References (56)
  1. Fast evaluation of the boltzmann collision operator using data driven reduced order models. Journal of Computational Physics 470, 111526.
  2. Uniformly stable numerical schemes for the boltzmann equation preserving the compressible navier–stokes asymptotics. Journal of Computational Physics 227, 3781–3803.
  3. A model for collision processes in gases. i. small amplitude processes in charged and neutral one-component systems. Physical review 94, 511.
  4. Molecular gas dynamics and the direct simulation of gas flows. Oxford university press.
  5. Tensor methods for the boltzmann-bgk equation. Journal of Computational Physics 421, 109744.
  6. High order central weno-implicit-explicit runge kutta schemes for the bgk model on general polygonal meshes. Journal of Computational Physics 422, 109766.
  7. JAX: composable transformations of Python+NumPy programs. URL: http://github.com/google/jax.
  8. The mathematical theory of non-uniform gases: an account of the kinetic theory of viscosity, thermal conduction and diffusion in gases. Cambridge university press.
  9. Symbolic discovery of optimization algorithms. arXiv preprint arXiv:2302.06675 .
  10. Separable physics-informed neural networks. Advances in Neural Information Processing Systems 36.
  11. Conservative semi-lagrangian schemes for kinetic equations part ii: Applications. Journal of Computational Physics 436, 110281.
  12. Approximation by superpositions of a sigmoidal function. Mathematics of control, signals and systems 2, 303–314.
  13. Towards an ultra efficient kinetic scheme. part i: Basics on the bgk equation. Journal of Computational Physics 255, 680–698.
  14. An efficient numerical method for solving the boltzmann equation in multidimensions. Journal of Computational Physics 353, 46–81.
  15. Numerical methods for kinetic equations. Acta Numerica 23, 369–520.
  16. Semi-lagrangian nodal discontinuous galerkin method for the bgk model. arXiv preprint arXiv:2105.02421 .
  17. A class of asymptotic-preserving schemes for kinetic equations and related problems with stiff sources. Journal of Computational Physics 229, 7625–7648.
  18. Micro-macro decomposition based asymptotic-preserving numerical schemes and numerical moments conservation for collisional nonlinear kinetic equations. Journal of Computational Physics 382, 264–290.
  19. A local macroscopic conservative (lomac) low rank tensor method with the discontinuous galerkin method for the vlasov dynamics. Communications on Applied Mathematics and Computation , 1–26.
  20. A conservative low rank tensor method for the vlasov dynamics. SIAM Journal on Scientific Computing 46, A232–A263. doi:10.1137/22M1473960.
  21. Uniformly accurate machine learning-based hydrodynamic models for kinetic equations. Proceedings of the National Academy of Sciences 116, 21983–21991.
  22. The framework of plasma physics. CRC Press.
  23. The expression of a tensor or a polyadic as a sum of products. Journal of Mathematics and Physics 6, 164–189.
  24. Hutchinson trace estimation for high-dimensional and high-order physics-informed neural networks. arXiv preprint arXiv:2312.14499 .
  25. Tackling the curse of dimensionality with physics-informed neural networks. arXiv preprint arXiv:2307.12306 .
  26. Matlab version: 9.13.0 (r2022b). URL: https://www.mathworks.com.
  27. A micro-macro decomposition-based asymptotic-preserving scheme for the multispecies boltzmann equation. SIAM Journal on Scientific Computing 31, 4580–4606.
  28. Universal approximation with deep narrow networks, in: Conference on learning theory, PMLR. pp. 2306–2327.
  29. Adam: A method for stochastic optimization. arXiv preprint arXiv:1412.6980 .
  30. oppinn: Physics-informed neural network with operator learning to approximate solutions to the fokker-planck-landau equation. Journal of Computational Physics 480, 112031.
  31. Finite element operator network for solving parametric pdes. arXiv:2308.04690.
  32. Computational methods of neutron transport. John Wiley and Sons, Inc., New York, NY.
  33. Solving boltzmann equation with neural sparse representation. arXiv preprint arXiv:2302.09233 .
  34. Convergence of the fourier-galerkin spectral method for the boltzmann equation with uncertainties. arXiv:2212.04083.
  35. Sgdr: Stochastic gradient descent with warm restarts, in: International Conference on Learning Representations.
  36. Physics-informed neural networks for solving forward and inverse flow problems via the boltzmann-bgk formulation. Journal of Computational Physics 447, 110676.
  37. Physics-informed neural networks with hard constraints for inverse design. SIAM Journal on Scientific Computing 43, B1105–B1132.
  38. Semiconductor equations. Springer Science & Business Media.
  39. Discrete velocity model and implicit scheme for the bgk equation of rarefied gas dynamics. Mathematical Models and Methods in Applied Sciences 10, 1121–1149.
  40. Neural-network based collision operators for the boltzmann equation. Journal of Computational Physics 470, 111541.
  41. Fast algorithms for computing the boltzmann collision operator. Mathematics of computation 75, 1833–1852.
  42. Achieving high accuracy with pinns via energy natural gradient descent, in: International Conference on Machine Learning, PMLR. pp. 25471–25485.
  43. A fourier spectral method for homogeneous boltzmann equations. Transport Theory and Statistical Physics 25, 369–382.
  44. Numerical solution of the boltzmann equation i: Spectrally accurate approximation of the collision operator. SIAM journal on numerical analysis 37, 1217–1245.
  45. Implicit–explicit schemes for bgk kinetic equations. Journal of Scientific Computing 32, 1–28.
  46. Data-driven, structure-preserving approximations to entropy-based moment closures for kinetic equations. arXiv preprint arXiv:2106.08973 .
  47. Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational physics 378, 686–707.
  48. Openbte: a solver for ab-initio phonon transport in multidimensional structures. arXiv preprint arXiv:2106.02764 .
  49. Randomized forward mode of automatic differentiation for optimization algorithms. arXiv preprint arXiv:2310.14168 .
  50. Implicit neural representations with periodic activation functions. Advances in neural information processing systems 33, 7462–7473.
  51. Accelerating kinetic simulations of electrostatic plasmas with reduced-order modeling. arXiv preprint arXiv:2310.18493 .
  52. A review of mathematical topics in collisional kinetic theory. Handbook of mathematical fluid dynamics 1, 3–8.
  53. An expert’s guide to training physics-informed neural networks. arXiv preprint arXiv:2308.08468 .
  54. Relaxnet: A structure-preserving neural network to approximate the boltzmann collision operator. Journal of Computational Physics , 112317.
  55. High order asymptotic preserving nodal discontinuous galerkin imex schemes for the bgk equation. Journal of Computational Physics 284, 70–94.
  56. Physics-informed neural networks for solving time-dependent mode-resolved phonon boltzmann transport equation. npj Computational Materials 9, 212.
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