Related papers: Graph Neural Networks with Similarity-Navigated Probabilistic Feature Copying

Graph Neural Networks with Similarity-Navigated Probabilistic Feature Copying

URL: http://arxiv.org/abs/2509.19084v1
Date: Tue, 23 Sep 2025 14:39:09 GMT
Title: Graph Neural Networks with Similarity-Navigated Probabilistic Feature Copying
Authors: Asela Hevapathige,
Abstract summary: We propose AxelGNN, a novel GNN architecture inspired by Axelrod's cultural dissemination model.<n>AxelGNN incorporates similarity-gated probabilistic interactions that adaptively promote convergence or divergence based on node similarity.<n>It consistently outperforms or matches state-of-the-art GNN methods across diverse graph structures with varying homophily-heterophily characteristics.
Score: 1.5229257192293202
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Graph Neural Networks (GNNs) have demonstrated remarkable success across various graph-based tasks. However, they face some fundamental limitations: feature oversmoothing can cause node representations to become indistinguishable in deeper networks, they struggle to effectively manage heterogeneous relationships where connected nodes differ significantly, and they process entire feature vectors as indivisible units, which limits flexibility. We seek to address these limitations. We propose AxelGNN, a novel GNN architecture inspired by Axelrod's cultural dissemination model that addresses these limitations through a unified framework. AxelGNN incorporates similarity-gated probabilistic interactions that adaptively promote convergence or divergence based on node similarity, implements trait-level copying mechanisms for fine-grained feature aggregation at the segment level, and maintains global polarization to preserve node distinctiveness across multiple representation clusters. The model's bistable convergence dynamics naturally handle both homophilic and heterophilic graphs within a single architecture. Extensive experiments on node classification and influence estimation benchmarks demonstrate that AxelGNN consistently outperforms or matches state-of-the-art GNN methods across diverse graph structures with varying homophily-heterophily characteristics.

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