Related papers: Solving nonlinear subsonic compressible flow in infinite domain via multi-stage neural networks

Solving nonlinear subsonic compressible flow in infinite domain via multi-stage neural networks

URL: http://arxiv.org/abs/2601.00342v1
Date: Thu, 01 Jan 2026 13:46:01 GMT
Title: Solving nonlinear subsonic compressible flow in infinite domain via multi-stage neural networks
Authors: Xuehui Qian, Hongkai Tao, Yongji Wang,
Abstract summary: In aerodynamics, accurately modeling subsonic compressible flow over airfoils is critical for aircraft design.<n>Traditional approaches often rely on linearized equations or finite, truncated domains, which introduce non-negligible errors and limit applicability in real-world scenarios.<n>We propose a novel framework utilizing Physics-Informed Networks (PINNs) to solve the full nonlinear compressible potential equation in an unbounded domain.
Score: 1.1317872970491056
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: In aerodynamics, accurately modeling subsonic compressible flow over airfoils is critical for aircraft design. However, solving the governing nonlinear perturbation velocity potential equation presents computational challenges. Traditional approaches often rely on linearized equations or finite, truncated domains, which introduce non-negligible errors and limit applicability in real-world scenarios. In this study, we propose a novel framework utilizing Physics-Informed Neural Networks (PINNs) to solve the full nonlinear compressible potential equation in an unbounded (infinite) domain. We address the unbounded-domain and convergence challenges inherent in standard PINNs by incorporating a coordinate transformation and embedding physical asymptotic constraints directly into the network architecture. Furthermore, we employ a Multi-Stage PINN (MS-PINN) approach to iteratively minimize residuals, achieving solution accuracy approaching machine precision. We validate this framework by simulating flow over circular and elliptical geometries, comparing our results against traditional finite-domain and linearized solutions. Our findings quantify the noticeable discrepancies introduced by domain truncation and linearization, particularly at higher Mach numbers, and demonstrate that this new framework is a robust, high-fidelity tool for computational fluid dynamics.

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