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Main Authors: Yu, Fangzhou, Su, Yiqi, Lee, Ray, Cheng, Shenfeng, Ramakrishnan, Naren
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.23861
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author Yu, Fangzhou
Su, Yiqi
Lee, Ray
Cheng, Shenfeng
Ramakrishnan, Naren
author_facet Yu, Fangzhou
Su, Yiqi
Lee, Ray
Cheng, Shenfeng
Ramakrishnan, Naren
contents Neural ODEs are increasingly used as continuous-time models for scientific and sensor data, but unconstrained neural ODEs can drift and violate domain invariants (e.g., conservation laws), yielding physically implausible solutions. In turn, this can compound error in long-horizon prediction and surrogate simulation. Existing solutions typically aim to enforce invariance by soft penalties or other forms of regularization, which can reduce overall error but do not guarantee that trajectories will not leave the constraint manifold. We introduce the invariant compiler, a framework that enforces invariants by construction: it treats invariants as first-class types and uses an LLM-driven compilation workflow to translate a generic neural ODE specification into a structure-preserving architecture whose trajectories remain on the admissible manifold in continuous time (and up to numerical integration error in practice). This compiler view cleanly separates what must be preserved (scientific structure) from what is learned from data (dynamics within that structure). It provides a systematic design pattern for invariant-respecting neural surrogates across scientific domains.
format Preprint
id arxiv_https___arxiv_org_abs_2603_23861
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle An Invariant Compiler for Neural ODEs in AI-Accelerated Scientific Simulation
Yu, Fangzhou
Su, Yiqi
Lee, Ray
Cheng, Shenfeng
Ramakrishnan, Naren
Machine Learning
Neural ODEs are increasingly used as continuous-time models for scientific and sensor data, but unconstrained neural ODEs can drift and violate domain invariants (e.g., conservation laws), yielding physically implausible solutions. In turn, this can compound error in long-horizon prediction and surrogate simulation. Existing solutions typically aim to enforce invariance by soft penalties or other forms of regularization, which can reduce overall error but do not guarantee that trajectories will not leave the constraint manifold. We introduce the invariant compiler, a framework that enforces invariants by construction: it treats invariants as first-class types and uses an LLM-driven compilation workflow to translate a generic neural ODE specification into a structure-preserving architecture whose trajectories remain on the admissible manifold in continuous time (and up to numerical integration error in practice). This compiler view cleanly separates what must be preserved (scientific structure) from what is learned from data (dynamics within that structure). It provides a systematic design pattern for invariant-respecting neural surrogates across scientific domains.
title An Invariant Compiler for Neural ODEs in AI-Accelerated Scientific Simulation
topic Machine Learning
url https://arxiv.org/abs/2603.23861