Sub-Sequential Physics-Informed Learning with State Space Model

Chenhui Xu; Dancheng Liu; Yuting Hu; Jiajie Li; Ruiyang Qin; Qingxiao Zheng; Jinjun Xiong

Sub-Sequential Physics-Informed Learning with State Space Model

Chenhui Xu
, Dancheng Liu
, Yuting Hu
, Jiajie Li
, Ruiyang Qin
, Qingxiao Zheng
, Jinjun Xiong

Department of Computer Science and Engineering

SUNY Buffalo
University of Notre Dame

Research output: Contribution to journal › Conference article › peer-review

Abstract

Physics-Informed Neural Networks (PINNs) are a kind of deep-learning-based numerical solvers for partial differential equations (PDEs). Existing PINNs often suffer from failure modes of being unable to propagate patterns of initial conditions. We discover that these failure modes are caused by the simplicity bias of neural networks and the mismatch between PDE’s continuity and PINN’s discrete sampling. We reveal that the State Space Model (SSM) can be a continuous-discrete articulation allowing initial condition propagation, and that simplicity bias can be eliminated by aligning a sequence of moderate granularity. Accordingly, we propose PINNMamba, a novel framework that introduces subsequence modeling with SSM. Experimental results show that PINNMamba can reduce errors by up to 86.3% compared with state-of-the-art architecture. Our code is available at https://github.com/miniHuiHui/PINNMamba.

Original language	English
Pages (from-to)	69507-69525
Number of pages	19
Journal	Proceedings of Machine Learning Research
Volume	267
State	Published - 2025
Event	42nd International Conference on Machine Learning, ICML 2025 - Vancouver, Canada Duration: Jul 13 2025 → Jul 19 2025

Cite this

@article{86610482647048efb43315b6760fe925,

title = "Sub-Sequential Physics-Informed Learning with State Space Model",

abstract = "Physics-Informed Neural Networks (PINNs) are a kind of deep-learning-based numerical solvers for partial differential equations (PDEs). Existing PINNs often suffer from failure modes of being unable to propagate patterns of initial conditions. We discover that these failure modes are caused by the simplicity bias of neural networks and the mismatch between PDE{\textquoteright}s continuity and PINN{\textquoteright}s discrete sampling. We reveal that the State Space Model (SSM) can be a continuous-discrete articulation allowing initial condition propagation, and that simplicity bias can be eliminated by aligning a sequence of moderate granularity. Accordingly, we propose PINNMamba, a novel framework that introduces subsequence modeling with SSM. Experimental results show that PINNMamba can reduce errors by up to 86.3\% compared with state-of-the-art architecture. Our code is available at https://github.com/miniHuiHui/PINNMamba.",

author = "Chenhui Xu and Dancheng Liu and Yuting Hu and Jiajie Li and Ruiyang Qin and Qingxiao Zheng and Jinjun Xiong",

note = "Publisher Copyright: {\textcopyright} 2025 by the author(s).; 42nd International Conference on Machine Learning, ICML 2025 ; Conference date: 13-07-2025 Through 19-07-2025",

year = "2025",

language = "English",

volume = "267",

pages = "69507--69525",

journal = "Proceedings of Machine Learning Research",

issn = "2640-3498",

publisher = "ML Research Press",

}

TY - JOUR

T1 - Sub-Sequential Physics-Informed Learning with State Space Model

AU - Xu, Chenhui

AU - Liu, Dancheng

AU - Hu, Yuting

AU - Li, Jiajie

AU - Qin, Ruiyang

AU - Zheng, Qingxiao

AU - Xiong, Jinjun

PY - 2025

Y1 - 2025

N2 - Physics-Informed Neural Networks (PINNs) are a kind of deep-learning-based numerical solvers for partial differential equations (PDEs). Existing PINNs often suffer from failure modes of being unable to propagate patterns of initial conditions. We discover that these failure modes are caused by the simplicity bias of neural networks and the mismatch between PDE’s continuity and PINN’s discrete sampling. We reveal that the State Space Model (SSM) can be a continuous-discrete articulation allowing initial condition propagation, and that simplicity bias can be eliminated by aligning a sequence of moderate granularity. Accordingly, we propose PINNMamba, a novel framework that introduces subsequence modeling with SSM. Experimental results show that PINNMamba can reduce errors by up to 86.3% compared with state-of-the-art architecture. Our code is available at https://github.com/miniHuiHui/PINNMamba.

AB - Physics-Informed Neural Networks (PINNs) are a kind of deep-learning-based numerical solvers for partial differential equations (PDEs). Existing PINNs often suffer from failure modes of being unable to propagate patterns of initial conditions. We discover that these failure modes are caused by the simplicity bias of neural networks and the mismatch between PDE’s continuity and PINN’s discrete sampling. We reveal that the State Space Model (SSM) can be a continuous-discrete articulation allowing initial condition propagation, and that simplicity bias can be eliminated by aligning a sequence of moderate granularity. Accordingly, we propose PINNMamba, a novel framework that introduces subsequence modeling with SSM. Experimental results show that PINNMamba can reduce errors by up to 86.3% compared with state-of-the-art architecture. Our code is available at https://github.com/miniHuiHui/PINNMamba.

UR - https://www.scopus.com/pages/publications/105023832425

M3 - Conference article

AN - SCOPUS:105023832425

SN - 2640-3498

VL - 267

SP - 69507

EP - 69525

JO - Proceedings of Machine Learning Research

JF - Proceedings of Machine Learning Research

T2 - 42nd International Conference on Machine Learning, ICML 2025

Y2 - 13 July 2025 through 19 July 2025

ER -

Sub-Sequential Physics-Informed Learning with State Space Model

Abstract

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