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Refining Euclidean Obfuscatory Nodes Helps: A Joint-Space Graph Learning Method for Graph Neural Networks.

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    This study introduces joint-space graph learning (JSGL) for graph neural networks (GNNs). JSGL refines graph topology in hyperbolic space to address issues with Euclidean embeddings and improve node classification accuracy.

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    Area of Science:

    • Machine Learning
    • Graph Neural Networks
    • Data Mining

    Background:

    • Graph neural networks (GNNs) require predefined graph structures, limiting their applicability.
    • Existing methods jointly learn graph structure and GNN parameters but often assume constant space curvature (Euclidean or hyperbolic).
    • Constant curvature assumptions can lead to obfuscatory nodes, hindering accurate node embedding and classification.

    Purpose of the Study:

    • To propose a novel joint-space graph learning (JSGL) method for GNNs that handles non-constant curvatures.
    • To effectively identify and refine embeddings of obfuscatory nodes in graph learning.

    Main Methods:

    • JSGL learns an initial graph structure using Euclidean embeddings.
    • It identifies obfuscatory nodes within the Euclidean space.
    • The graph topology near these obfuscatory nodes is then refined using hyperbolic space embeddings.

    Main Results:

    • JSGL successfully identifies obfuscatory nodes that are improperly embedded.
    • The proposed method demonstrates superior performance compared to various baseline methods in experimental evaluations.
    • Theoretical justification is provided for the obfuscatory node identification mechanism.

    Conclusions:

    • JSGL offers an effective approach for learning graph structures in the presence of non-constant curvatures.
    • The joint Euclidean-hyperbolic space refinement addresses limitations of existing GNN graph learning methods.
    • This method enhances the robustness and accuracy of GNNs when graph structures are initially unknown or complex.