Gespeichert in:
Bibliographische Detailangaben
Hauptverfasser: Song, Jingtai, Zhu, Qinsheng, Xing, Xiaodong, Tang, Yufeng, Zhang, Zhiyun, Zhang, Xianwen, Wu, Hao
Format: Preprint
Veröffentlicht: 2026
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2605.12544
Tags: Tag hinzufügen
Keine Tags, Fügen Sie den ersten Tag hinzu!
_version_ 1866909038279655424
author Song, Jingtai
Zhu, Qinsheng
Xing, Xiaodong
Tang, Yufeng
Zhang, Zhiyun
Zhang, Xianwen
Wu, Hao
author_facet Song, Jingtai
Zhu, Qinsheng
Xing, Xiaodong
Tang, Yufeng
Zhang, Zhiyun
Zhang, Xianwen
Wu, Hao
contents Quantifying hemodynamics in the curved segments of the intracranial internal carotid artery is a core challenge in diagnosing vascular stenosis. Conventional full-field imaging, such as 4D Flow MRI, is costly and difficult to widely promote. Meanwhile, reconstructing full-field fluid information from easily accessible and non-invasive sparse measurement data (such as transcranial Doppler ultrasound/computed tomography angiography) is essentially a highly challenging ill-posed inverse problem. To overcome the severe optimization difficulties and generalization failures of conventional physics-informed neural networks (PINNs) in highly tortuous geometries, we propose a dual-correction physics-informed neural network (DCP-INN) framework taking into account a causal decoupling strategy. The proposed DCP-INN model utilizes a diamond-shaped main network to capture low-frequency trends in physical evolution, and employs a parallel wide-deep correction network to compensate for high-frequency residuals resulting from complex geometric shapes. Furthermore, the framework introduces a high-order physical loss function based on Taylor expansion to enhance local continuity under extremely sparse data constraints. To validate the proposed method, we performed computational evaluations on realistic vascular geometries with significant tortuosity. The results demonstrate that the method effectively mitigates optimization challenges and significantly reduces flow field reconstruction error. This study not only achieves physically credible and robust flow field reconstruction in complex morphologies but also provides a highly promising algorithmic foundation for building low-cost, high-resolution personalized cardiovascular digital twins in future.
format Preprint
id arxiv_https___arxiv_org_abs_2605_12544
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Dual-Correction Physics-Informed Neural Networks for Hemodynamic Reconstruction from Sparse Data
Song, Jingtai
Zhu, Qinsheng
Xing, Xiaodong
Tang, Yufeng
Zhang, Zhiyun
Zhang, Xianwen
Wu, Hao
Medical Physics
Quantifying hemodynamics in the curved segments of the intracranial internal carotid artery is a core challenge in diagnosing vascular stenosis. Conventional full-field imaging, such as 4D Flow MRI, is costly and difficult to widely promote. Meanwhile, reconstructing full-field fluid information from easily accessible and non-invasive sparse measurement data (such as transcranial Doppler ultrasound/computed tomography angiography) is essentially a highly challenging ill-posed inverse problem. To overcome the severe optimization difficulties and generalization failures of conventional physics-informed neural networks (PINNs) in highly tortuous geometries, we propose a dual-correction physics-informed neural network (DCP-INN) framework taking into account a causal decoupling strategy. The proposed DCP-INN model utilizes a diamond-shaped main network to capture low-frequency trends in physical evolution, and employs a parallel wide-deep correction network to compensate for high-frequency residuals resulting from complex geometric shapes. Furthermore, the framework introduces a high-order physical loss function based on Taylor expansion to enhance local continuity under extremely sparse data constraints. To validate the proposed method, we performed computational evaluations on realistic vascular geometries with significant tortuosity. The results demonstrate that the method effectively mitigates optimization challenges and significantly reduces flow field reconstruction error. This study not only achieves physically credible and robust flow field reconstruction in complex morphologies but also provides a highly promising algorithmic foundation for building low-cost, high-resolution personalized cardiovascular digital twins in future.
title Dual-Correction Physics-Informed Neural Networks for Hemodynamic Reconstruction from Sparse Data
topic Medical Physics
url https://arxiv.org/abs/2605.12544