Discovering Physical Directions in Weight Space: Composing Neural PDE Experts
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Computer Science > Machine Learning
arXiv:2605.14546 (cs)
[Submitted on 14 May 2026]
Title:Discovering Physical Directions in Weight Space: Composing Neural PDE Experts
Authors:Pengkai Wang, Pengwei Liu, Yuanyi Wang, Guanyu Chen, Xingyu Ren, Xiaolong Li, Zhongkai Hao, Yuting Kong, Qixin Zhang, Dong Ni
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Abstract:Recent advances in neural operators have made partial differential equation (PDE) surrogate modeling increasingly scalable and transferable through large-scale pretraining and in-context adaptation. However, after a shared operator is fine-tuned to multiple regimes within a continuous physical family, it remains unclear whether the resulting weight-space updates merely form isolated regime experts or reveal reusable physical structure. Starting from a shared family anchor, we fine-tune low- and high-regime endpoint experts and show that their updates can be separated into a family-shared adaptation and a direction aligned with the underlying physical parameter. This separation reinterprets endpoint experts as finite-difference probes of a local physical direction in weight space, explaining why static averaging can interpolate between regimes but attenuates endpoint-specific physics. Building on this perspective, we propose Calibration-Conditioned Merge (CCM), a post-hoc coordinate readout method for composing neural PDE experts along this physical direction. Given physical metadata, a calibrated coordinate mapping, or a short observed rollout prefix, CCM infers the target composition coordinate and deploys a single merged checkpoint for the remaining rollout. We evaluate CCM on the reaction--diffusion system, viscosity-parameterized two-dimensional Navier--Stokes equations, and radial dam-break dynamics. Across these benchmarks, CCM achieves its strongest gains in extrapolative regimes, reducing out-of-distribution rollout error relative to the family anchor by 54.2%, 42.8%, and 13.8%, respectively. Further experiments across FNO scales, a DPOT-style backbone, and ablations confirm that endpoint fine-tuning is not arbitrary checkpoint drift, but reveals a calibratable physical direction for training-free transfer across PDE regimes.
| Subjects: | Machine Learning (cs.LG) |
| Cite as: | arXiv:2605.14546 [cs.LG] |
| (or arXiv:2605.14546v1 [cs.LG] for this version) | |
| https://doi.org/10.48550/arXiv.2605.14546
arXiv-issued DOI via DataCite (pending registration)
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View a PDF of the paper titled Discovering Physical Directions in Weight Space: Composing Neural PDE Experts, by Pengkai Wang and 9 other authors
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