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arxiv: 2407.07218 · v1 · pith:OZIW3C3Vnew · submitted 2024-07-09 · 🧮 math.NA · cs.LG· cs.NA· physics.flu-dyn

Weak baselines and reporting biases lead to overoptimism in machine learning for fluid-related partial differential equations

classification 🧮 math.NA cs.LGcs.NAphysics.flu-dyn
keywords reportingbiasbiasesleadresultsweakbaselinebaselines
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One of the most promising applications of machine learning (ML) in computational physics is to accelerate the solution of partial differential equations (PDEs). The key objective of ML-based PDE solvers is to output a sufficiently accurate solution faster than standard numerical methods, which are used as a baseline comparison. We first perform a systematic review of the ML-for-PDE solving literature. Of articles that use ML to solve a fluid-related PDE and claim to outperform a standard numerical method, we determine that 79% (60/76) compare to a weak baseline. Second, we find evidence that reporting biases, especially outcome reporting bias and publication bias, are widespread. We conclude that ML-for-PDE solving research is overoptimistic: weak baselines lead to overly positive results, while reporting biases lead to underreporting of negative results. To a large extent, these issues appear to be caused by factors similar to those of past reproducibility crises: researcher degrees of freedom and a bias towards positive results. We call for bottom-up cultural changes to minimize biased reporting as well as top-down structural reforms intended to reduce perverse incentives for doing so.

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