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Variational graph p-Laplacian eigendecomposition under p-orthogonality constraints

Author

Listed:
  • Alessandro Lanza

    (University of Bologna)

  • Serena Morigi

    (University of Bologna)

  • Giuseppe Recupero

    (University of Bologna)

Abstract

The p-Laplacian is a non-linear generalization of the Laplace operator. In the graph context, its eigenfunctions are used for data clustering, spectral graph theory, dimensionality reduction and other problems, as non-linearity better captures the underlying geometry of the data. We formulate the graph p-Laplacian nonlinear eigenproblem as an optimization problem under p-orthogonality constraints. The problem of computing multiple eigenpairs of the graph p-Laplacian is then approached incrementally by minimizing the graph Rayleigh quotient under nonlinear constraints. A simple reformulation allows us to take advantage of linear constraints. We propose two different optimization algorithms to solve the variational problem. The first is a projected gradient descent on manifold, and the second is an Alternate Direction Method of Multipliers which leverages the scaling invariance of the graph Rayleigh quotient to solve a constrained minimization under p-orthogonality constraints. We demonstrate the effectiveness and accuracy of the proposed algorithms and compare them in terms of efficiency.

Suggested Citation

  • Alessandro Lanza & Serena Morigi & Giuseppe Recupero, 2025. "Variational graph p-Laplacian eigendecomposition under p-orthogonality constraints," Computational Optimization and Applications, Springer, vol. 91(2), pages 787-825, June.
    • Handle: RePEc:spr:coopap:v:91:y:2025:i:2:d:10.1007_s10589-024-00631-2
    DOI: 10.1007/s10589-024-00631-2
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