FlowBench: A Large Scale Benchmark for Flow Simulation over Complex
Geometries
- URL: http://arxiv.org/abs/2409.18032v1
- Date: Thu, 26 Sep 2024 16:38:48 GMT
- Title: FlowBench: A Large Scale Benchmark for Flow Simulation over Complex
Geometries
- Authors: Ronak Tali, Ali Rabeh, Cheng-Hau Yang, Mehdi Shadkhah, Samundra Karki,
Abhisek Upadhyaya, Suriya Dhakshinamoorthy, Marjan Saadati, Soumik Sarkar,
Adarsh Krishnamurthy, Chinmay Hegde, Aditya Balu, Baskar Ganapathysubramanian
- Abstract summary: FlowBench is a dataset for neural simulators with over 10K samples.
FlowBench will enable evaluating the interplay between complex geometry, coupled flow phenomena, and data sufficiency on the performance of neural PDE solvers.
- Score: 19.15738125919099
- License: http://creativecommons.org/licenses/by-nc-sa/4.0/
- Abstract: Simulating fluid flow around arbitrary shapes is key to solving various
engineering problems. However, simulating flow physics across complex
geometries remains numerically challenging and computationally
resource-intensive, particularly when using conventional PDE solvers. Machine
learning methods offer attractive opportunities to create fast and adaptable
PDE solvers. However, benchmark datasets to measure the performance of such
methods are scarce, especially for flow physics across complex geometries. We
introduce FlowBench, a dataset for neural simulators with over 10K samples,
which is currently larger than any publicly available flow physics dataset.
FlowBench contains flow simulation data across complex geometries
(\textit{parametric vs. non-parametric}), spanning a range of flow conditions
(\textit{Reynolds number and Grashoff number}), capturing a diverse array of
flow phenomena (\textit{steady vs. transient; forced vs. free convection}), and
for both 2D and 3D. FlowBench contains over 10K data samples, with each sample
the outcome of a fully resolved, direct numerical simulation using a
well-validated simulator framework designed for modeling transport phenomena in
complex geometries. For each sample, we include velocity, pressure, and
temperature field data at 3 different resolutions and several summary
statistics features of engineering relevance (such as coefficients of lift and
drag, and Nusselt numbers). %Additionally, we include masks and signed distance
fields for each shape. We envision that FlowBench will enable evaluating the
interplay between complex geometry, coupled flow phenomena, and data
sufficiency on the performance of current, and future, neural PDE solvers. We
enumerate several evaluation metrics to help rank order the performance of
neural PDE solvers. We benchmark the performance of several baseline methods
including FNO, CNO, WNO, and DeepONet.
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