CATO: Charted Attention for Neural PDE Operators

TL;DR

CATO introduces a geometry-adaptive, derivative-aware neural operator that learns continuous charts to efficiently model PDEs on complex geometries, achieving significant accuracy and parameter reduction.

Contribution

The paper proposes CATO, a novel neural operator that learns continuous charts and incorporates physics-informed loss for improved PDE modeling on complex geometries.

Findings

CATO outperforms baselines by approximately 26.76% on all datasets.

CATO reduces model parameters by 81.98% compared to competitors.

Theoretical results show low-rank representation and bounded error with small chart perturbations.

Abstract

Neural operators have emerged as powerful data-driven solvers for PDEs, offering substantial acceleration over classical numerical methods. However, existing transformer-based operators still face critical challenges when modeling PDEs on complex geometries: directly processing over massive mesh points is computationally expensive, while operating in raw discretization coordinates may obscure the intrinsic geometry where physical interactions are more naturally expressed. To address these limitations, we introduce the Charted Axial Transformer Operator (CATO), a geometry-adaptive and derivative-aware neural operator for PDEs on general geometries. Instead of applying attention directly in the physical coordinate system, CATO learns a continuous latent chart that maps mesh coordinates into a learned chart space, where chart-conditioned axial attention efficiently captures long-range dependencies with reduced computational cost. In addition, CATO introduces a derivative-aware physics loss for steady-state PDEs that jointly supervises solution values, mesh-consistent gradients, and an auxiliary flux-like field, improving physical fidelity and reducing oversmoothing. We further provide a theoretical approximation result showing that, under a favorable chart, charted axial attention can represent low-rank axial solution operators with controlled error, and that small chart perturbations induce bounded approximation degradation. CATO achieves the best performance across all evaluated datasets, yielding an average improvement of approximately 26.76\% over the strongest competing baselines while reducing the number of parameters by 81.98\%. These results highlight the effectiveness of learning geometry-adaptive charts and derivative-aware physical supervision for accurate and efficient PDE operator learning.