基于相位保持的频域MinMax框架图增强方法

doi:10.11896/jsjkx.250700069

计算机科学 ›› 2026, Vol. 53 ›› Issue (4): 245-251.doi: 10.11896/jsjkx.250700069

• 数据库&大数据&数据科学 • 上一篇下一篇

基于相位保持的频域MinMax框架图增强方法

华彧, 周效成, 沈项军, 刘志锋, 周从华

江苏大学计算机科学与通信工程学院江苏镇江 212013

收稿日期:2025-07-14 修回日期:2025-09-05 出版日期:2026-04-15 发布日期:2026-04-08
通讯作者: 沈项军(xjshen@ujs.edu.cn)
作者简介:(2212408023@stmail.ujs.cn)
基金资助:
国家自然科学基金(62376108)

Phase-preserved MinMax Framework for Graph Augmentation in Frequency Domain

HUA Yu, ZHOU Xiaocheng, SHEN Xiangjun, LIU Zhifeng, ZHOU Conghua

School of Computer Science and Communication Engineering, Jiangsu University, Zhenjiang, Jiangsu 212013, China

Received:2025-07-14 Revised:2025-09-05 Published:2026-04-15 Online:2026-04-08
About author:HUA Yu,born in 2002,postgraduate.His main research interests include graph neural networks and deep learning.
SHEN Xiangjun,born in 1977,Ph.D,professor,is a member of CCF(No.E200029891M).His main research interests include cross multimedia analysis,computer vision,pattern recognition and statistical machine learning.
Supported by:
National Natural Science Foundation of China(62376108).

摘要/Abstract

摘要： 图数据增强通过对图结构或节点特征进行局部或全局变换,可有效提高图网络的泛化能力和鲁棒性。现有研究表明,图增强技术能够有效利用低频信息以获取图的全局拓扑,但是对于获取图网络细节结构上的高频信息仍存在一定不足,导致模型在学习图网络的局部特征时可能出现信息丢失或特征偏差。针对这一问题,提出了一种基于相位保持的频域MinMax框架图增强方法。该方法首先将频域处理与现有的MinMax框架相结合,将图数据划分为高频和低频部分。低频代表图的全局拓扑结构信息,而高频则代表图的丰富的细节信息。通过引入频域上的MinMax框架,模型可以更好地保留图的全局拓扑信息并增强高频细节部分,从而更好地捕捉图的多尺度结构。同时,采用自适应增强策略,根据不同频率分量的特征动态调整增强幅度,以提高训练效率。此外,频域相位信息反映了图节点的特征结构,通过在图数据中保留关键的相位信息,进一步提升了图数据的表达能力,为图神经网络提供了更为丰富和精准的特征表示。因此,所提方法从频域分析的角度,不仅保持了图拓扑的关键结构信息,还针对图节点数据特征进行有效增强,提高了模型对图数据的理解和泛化能力。在多个数据集上进行的实验表明,与传统方法相比,所提方法在图节点分类任务中将准确率提升了2个百分点以上。实验结果证明,所提方法在提升图模型性能的同时,也提高了计算效率,其在大规模图数据应用中的有效性与优势得到验证。

关键词: 图增强, 相位保持, 频域MinMax框架, 拓扑优化, 幅度调整

Abstract: Graph data augmentation enhances the generalization and robustness of graph neural networks(GNNs) by performing local or global transformations on graph structures or node features.While existing studies have shown that graph augmentation techniques can effectively leverage low-frequency information to capture the global topology of graphs,they often fail to preserve high-frequency components that encode fine-grained structural details.This shortcoming may result in information loss or feature distortion when learning local representations.To address this challenge,this paper proposes a phase-preserving frequency-domain MinMax framework for graph augmentation.The proposed method integrates frequency-domain analysis with the MinMax optimization paradigm,decomposing graph signals into low and high-frequency components.The low-frequency part captures global topological patterns,whereas the high-frequency part represents rich local structural information.By applying the MinMax strategy in the frequency domain,the proposed framework simultaneously preserves global structure and enhances high-frequency details,leading to more expressive multi-scale graph representations.In addition,it adopts an adaptive augmentation strategy that dynamically adjusts the perturbation amplitude based on the characteristics of different frequency components,thereby improving training efficiency.The phase information,which encodes intrinsic structural relations between graph nodes,is explicitly preserved to further enrich the expressive capacity of node representations.Through this frequency-aware design,the proposed method maintains essential topological structures while effectively enhancing node-level features,improving the GNN’s ability to capture both global and local semantics.Extensive experiments on multiple benchmark datasets demonstrate that the proposed method achieves over a 2 percentage points accuracy gain on node classification tasks compared to existing approaches.Moreover,it deli-vers superior computational efficiency,validating its effectiveness and scalability for large-scale graph learning scenarios.

Key words: Graph augmentation, Phase preservation, Frequency domain MinMax framework, Topological optimization, Amplitude adjustment

中图分类号:

TP181

华彧, 周效成, 沈项军, 刘志锋, 周从华. 基于相位保持的频域MinMax框架图增强方法[J]. 计算机科学, 2026, 53(4): 245-251. https://doi.org/10.11896/jsjkx.250700069

HUA Yu, ZHOU Xiaocheng, SHEN Xiangjun, LIU Zhifeng, ZHOU Conghua. Phase-preserved MinMax Framework for Graph Augmentation in Frequency Domain[J]. Computer Science, 2026, 53(4): 245-251. https://doi.org/10.11896/jsjkx.250700069

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基于相位保持的频域MinMax框架图增强方法

Phase-preserved MinMax Framework for Graph Augmentation in Frequency Domain

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