理论(学习稳定性)
操作员(生物学)
计算机科学
一般化
偏微分方程
编码器
功能(生物学)
人工神经网络
航程(航空)
参数统计
编码(内存)
应用数学
班级(哲学)
动力系统理论
数学
动态模态分解
算法
模式(计算机接口)
动力系统(定义)
人工智能
方案(数学)
分解
数学优化
偏导数
期限(时间)
深度学习
微分算子
序列(生物学)
分布参数系统
理论计算机科学
差速器(机械装置)
算符理论
微分方程
作者
Yi‐Chi Wang,Tian Lian Huang,Dandan Huang,Zhaohai Bai,Xuan Wang,Lin Ma,Haodi Zhang
标识
DOI:10.24963/ijcai.2025/1044
摘要
The deep operator networks (DON), a class of neural operators that learn mappings between function spaces, have recently emerged as surrogate models for parametric partial differential equations (PDEs). However, their full potential for accurately approximating general black-box PDEs remains underexplored due to challenges in training stability and performance, primarily arising from difficulties in learning mappings between low-dimensional inputs and high-dimensional outputs. Furthermore, inadequate encoding of input functions and query positions limits the generalization ability of DONs. To address these challenges, we propose the Dynamical Coupled Operator (DCO), which incorporates temporal dynamics to learn coupled functions, reducing information loss and improving training robustness. Additionally, we introduce an adaptive spectral input function encoder based on empirical mode decomposition to enhance input function representation, as well as a hybrid location encoder to improve query location encoding. We provide theoretical guarantees on the universal expressiveness of DCO, ensuring its applicability to a wide range of PDE problems. Extensive experiments on real-world, high-dimensional PDE datasets demonstrate that DCO significantly outperforms DONs.
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