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Main Authors: Wang, Yuhan, He, Silu, Luo, Qinyao, Yuan, Hongyuan, Zhao, Ling, Zhu, Jiawei, Li, Haifeng
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2503.19382
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author Wang, Yuhan
He, Silu
Luo, Qinyao
Yuan, Hongyuan
Zhao, Ling
Zhu, Jiawei
Li, Haifeng
author_facet Wang, Yuhan
He, Silu
Luo, Qinyao
Yuan, Hongyuan
Zhao, Ling
Zhu, Jiawei
Li, Haifeng
contents The existing methods learn geographic network representations through deep graph neural networks (GNNs) based on the i.i.d. assumption. However, the spatial heterogeneity and temporal dynamics of geographic data make the out-of-distribution (OOD) generalisation problem particularly salient. The latter are particularly sensitive to distribution shifts (feature and structural shifts) between testing and training data and are the main causes of the OOD generalisation problem. Spurious correlations are present between invariant and background representations due to selection biases and environmental effects, resulting in the model extremes being more likely to learn background representations. The existing approaches focus on background representation changes that are determined by shifts in the feature distributions of nodes in the training and test data while ignoring changes in the proportional distributions of heterogeneous and homogeneous neighbour nodes, which we refer to as structural distribution shifts. We propose a feature-structure mixed invariant representation learning (FSM-IRL) model that accounts for both feature distribution shifts and structural distribution shifts. To address structural distribution shifts, we introduce a sampling method based on causal attention, encouraging the model to identify nodes possessing strong causal relationships with labels or nodes that are more similar to the target node. Inspired by the Hilbert-Schmidt independence criterion, we implement a reweighting strategy to maximise the orthogonality of the node representations, thereby mitigating the spurious correlations among the node representations and suppressing the learning of background representations. Our experiments demonstrate that FSM-IRL exhibits strong learning capabilities on both geographic and social network datasets in OOD scenarios.
format Preprint
id arxiv_https___arxiv_org_abs_2503_19382
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Causal invariant geographic network representations with feature and structural distribution shifts
Wang, Yuhan
He, Silu
Luo, Qinyao
Yuan, Hongyuan
Zhao, Ling
Zhu, Jiawei
Li, Haifeng
Machine Learning
Artificial Intelligence
The existing methods learn geographic network representations through deep graph neural networks (GNNs) based on the i.i.d. assumption. However, the spatial heterogeneity and temporal dynamics of geographic data make the out-of-distribution (OOD) generalisation problem particularly salient. The latter are particularly sensitive to distribution shifts (feature and structural shifts) between testing and training data and are the main causes of the OOD generalisation problem. Spurious correlations are present between invariant and background representations due to selection biases and environmental effects, resulting in the model extremes being more likely to learn background representations. The existing approaches focus on background representation changes that are determined by shifts in the feature distributions of nodes in the training and test data while ignoring changes in the proportional distributions of heterogeneous and homogeneous neighbour nodes, which we refer to as structural distribution shifts. We propose a feature-structure mixed invariant representation learning (FSM-IRL) model that accounts for both feature distribution shifts and structural distribution shifts. To address structural distribution shifts, we introduce a sampling method based on causal attention, encouraging the model to identify nodes possessing strong causal relationships with labels or nodes that are more similar to the target node. Inspired by the Hilbert-Schmidt independence criterion, we implement a reweighting strategy to maximise the orthogonality of the node representations, thereby mitigating the spurious correlations among the node representations and suppressing the learning of background representations. Our experiments demonstrate that FSM-IRL exhibits strong learning capabilities on both geographic and social network datasets in OOD scenarios.
title Causal invariant geographic network representations with feature and structural distribution shifts
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2503.19382