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    Area of Science:

    • Artificial Intelligence
    • Machine Learning
    • Computational Science

    Background:

    • Graph neural networks (GNNs) offer efficient approximate solutions for combinatorial optimization problems (COPs).
    • Current backpropagation methods in GNNs often fall into local minima, limiting optimization performance.
    • Existing methods struggle to match the state-of-the-art (SOTA) in solving large-scale COPs.

    Purpose of the Study:

    • To develop a novel training algorithm for GNNs that overcomes the limitations of traditional backpropagation.
    • To improve the optimization performance of GNNs for solving complex combinatorial optimization problems.
    • To introduce a training method inspired by chaotic dynamics for enhanced GNN learning.

    Main Methods:

    • Introduced Chaotic Graph Backpropagation (CGBP), a new training algorithm for GNNs.
    • Incorporated a local loss function within the GNN training process to induce chaotic dynamics.
    • Leveraged the global ergodicity and pseudorandomness of chaotic dynamics for effective GNN learning.

    Main Results:

    • CGBP demonstrates efficient and global learning of GNNs for solving COPs.
    • Applied CGBP to Maximum Independent Set (MIS), Maximum Cut (MC), and Graph Coloring (GC) problems.
    • Achieved competitive or superior performance compared to SOTA methods on large-scale benchmark datasets.

    Conclusions:

    • CGBP effectively addresses the local minima problem in GNN training for COPs.
    • The chaotic dynamics in CGBP enable efficient and global optimization.
    • CGBP serves as a universal plug-in module to enhance existing learning methods for improved searching and performance.