Spatio-Temporal Graph Unlearning
- URL: http://arxiv.org/abs/2511.09404v1
- Date: Thu, 13 Nov 2025 01:52:32 GMT
- Title: Spatio-Temporal Graph Unlearning
- Authors: Qiming Guo, Wenbo Sun, Wenlu Wang,
- Abstract summary: CallosumNet is a divide-and-Bridging S-temporal graph unlearning framework inspired by the corpus callosum structure.<n>CallosumNet achieves complete unlearning with only 1%-2% relative MAE loss compared to the gold model.
- Score: 11.249016471516398
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Spatio-temporal graphs are widely used in modeling complex dynamic processes such as traffic forecasting, molecular dynamics, and healthcare monitoring. Recently, stringent privacy regulations such as GDPR and CCPA have introduced significant new challenges for existing spatio-temporal graph models, requiring complete unlearning of unauthorized data. Since each node in a spatio-temporal graph diffuses information globally across both spatial and temporal dimensions, existing unlearning methods primarily designed for static graphs and localized data removal cannot efficiently erase a single node without incurring costs nearly equivalent to full model retraining. Therefore, an effective approach for complete spatio-temporal graph unlearning is a pressing need. To address this, we propose CallosumNet, a divide-and-conquer spatio-temporal graph unlearning framework inspired by the corpus callosum structure that facilitates communication between the brain's two hemispheres. CallosumNet incorporates two novel techniques: (1) Enhanced Subgraph Construction (ESC), which adaptively constructs multiple localized subgraphs based on several factors, including biologically-inspired virtual ganglions; and (2) Global Ganglion Bridging (GGB), which reconstructs global spatio-temporal dependencies from these localized subgraphs, effectively restoring the full graph representation. Empirical results on four diverse real-world datasets show that CallosumNet achieves complete unlearning with only 1%-2% relative MAE loss compared to the gold model, significantly outperforming state-of-the-art baselines. Ablation studies verify the effectiveness of both proposed techniques.
Related papers
- Spatiotemporal Graph Learning with Direct Volumetric Information Passing and Feature Enhancement [62.91536661584656]
We propose a dual-module framework, Cell-embedded and Feature-enhanced Graph Neural Network (aka, CeFeGNN) for learning.<n>We embed learnable cell attributions to the common node-edge message passing process, which better captures the spatial dependency of regional features.<n>Experiments on various PDE systems and one real-world dataset demonstrate that CeFeGNN achieves superior performance compared with other baselines.
arXiv Detail & Related papers (2024-09-26T16:22:08Z) - Mending of Spatio-Temporal Dependencies in Block Adjacency Matrix [3.529869282529924]
We propose a novel end-to-end learning architecture designed to mend the temporal dependencies, resulting in a well-connected graph.
Our methodology demonstrates superior performance on benchmark datasets, such as SurgVisDom and C2D2.
arXiv Detail & Related papers (2023-10-04T06:42:33Z) - Spatial-Temporal Graph Learning with Adversarial Contrastive Adaptation [19.419836274690816]
We propose a new spatial-temporal graph learning model (GraphST) for enabling effective self-supervised learning.
Our proposed model is an adversarial contrastive learning paradigm that automates the distillation of crucial multi-view self-supervised information.
We demonstrate the superiority of our proposed GraphST method in various spatial-temporal prediction tasks on real-life datasets.
arXiv Detail & Related papers (2023-06-19T03:09:35Z) - Attention-based Spatial-Temporal Graph Convolutional Recurrent Networks
for Traffic Forecasting [12.568905377581647]
Traffic forecasting is one of the most fundamental problems in transportation science and artificial intelligence.
Existing methods cannot accurately model both long-term and short-term temporal correlations simultaneously.
We propose a novel spatial-temporal neural network framework, which consists of a graph convolutional recurrent module (GCRN) and a global attention module.
arXiv Detail & Related papers (2023-02-25T03:37:00Z) - Taming Local Effects in Graph-based Spatiotemporal Forecasting [28.30604130617646]
Stemporal graph neural networks have shown to be effective in time series forecasting applications.
This paper aims to understand the interplay between globality and locality in graph-basedtemporal forecasting.
We propose a methodological framework to rationalize the practice of including trainable node embeddings in such architectures.
arXiv Detail & Related papers (2023-02-08T14:18:56Z) - Localized Contrastive Learning on Graphs [110.54606263711385]
We introduce a simple yet effective contrastive model named Localized Graph Contrastive Learning (Local-GCL)
In spite of its simplicity, Local-GCL achieves quite competitive performance in self-supervised node representation learning tasks on graphs with various scales and properties.
arXiv Detail & Related papers (2022-12-08T23:36:00Z) - Continuous-Time and Multi-Level Graph Representation Learning for
Origin-Destination Demand Prediction [52.0977259978343]
This paper proposes a Continuous-time and Multi-level dynamic graph representation learning method for Origin-Destination demand prediction (CMOD)
The state vectors keep historical transaction information and are continuously updated according to the most recently happened transactions.
Experiments are conducted on two real-world datasets from Beijing Subway and New York Taxi, and the results demonstrate the superiority of our model against the state-of-the-art approaches.
arXiv Detail & Related papers (2022-06-30T03:37:50Z) - Optimal Propagation for Graph Neural Networks [51.08426265813481]
We propose a bi-level optimization approach for learning the optimal graph structure.
We also explore a low-rank approximation model for further reducing the time complexity.
arXiv Detail & Related papers (2022-05-06T03:37:00Z) - Spatio-Temporal Latent Graph Structure Learning for Traffic Forecasting [6.428566223253948]
We propose a new traffic forecasting framework--S-Temporal Latent Graph Structure Learning networks (ST-LGSL)
The model employs a graph based on Multilayer perceptron and K-Nearest Neighbor, which learns the latent graph topological information from the entire data.
With the dependencies-kNN based on ground-truth adjacency matrix and similarity metric in kNN, ST-LGSL aggregates the top focusing on geography and node similarity.
arXiv Detail & Related papers (2022-02-25T10:02:49Z) - Spatio-Temporal Joint Graph Convolutional Networks for Traffic
Forecasting [75.10017445699532]
Recent have shifted their focus towards formulating traffic forecasting as atemporal graph modeling problem.
We propose a novel approach for accurate traffic forecasting on road networks over multiple future time steps.
arXiv Detail & Related papers (2021-11-25T08:45:14Z) - Disentangling and Unifying Graph Convolutions for Skeleton-Based Action
Recognition [79.33539539956186]
We propose a simple method to disentangle multi-scale graph convolutions and a unified spatial-temporal graph convolutional operator named G3D.
By coupling these proposals, we develop a powerful feature extractor named MS-G3D based on which our model outperforms previous state-of-the-art methods on three large-scale datasets.
arXiv Detail & Related papers (2020-03-31T11:28:25Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.