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Hauptverfasser: Kiruluta, Andrew, Lemos, Andreas, Burity, Priscilla
Format: Preprint
Veröffentlicht: 2025
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2507.21190
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author Kiruluta, Andrew
Lemos, Andreas
Burity, Priscilla
author_facet Kiruluta, Andrew
Lemos, Andreas
Burity, Priscilla
contents We present a fully non neural learning framework based on Graph Laplacian Wavelet Transforms (GLWT). Unlike traditional architectures that rely on convolutional, recurrent, or attention based neural networks, our model operates purely in the graph spectral domain using structured multiscale filtering, nonlinear shrinkage, and symbolic logic over wavelet coefficients. Signals defined on graph nodes are decomposed via GLWT, modulated with interpretable nonlinearities, and recombined for downstream tasks such as denoising and token classification. The system supports compositional reasoning through a symbolic domain-specific language (DSL) over graph wavelet activations. Experiments on synthetic graph denoising and linguistic token graphs demonstrate competitive performance against lightweight GNNs with far greater transparency and efficiency. This work proposes a principled, interpretable, and resource-efficient alternative to deep neural architectures for learning on graphs.
format Preprint
id arxiv_https___arxiv_org_abs_2507_21190
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Beyond Neural Networks: Symbolic Reasoning over Wavelet Logic Graph Signals
Kiruluta, Andrew
Lemos, Andreas
Burity, Priscilla
Machine Learning
We present a fully non neural learning framework based on Graph Laplacian Wavelet Transforms (GLWT). Unlike traditional architectures that rely on convolutional, recurrent, or attention based neural networks, our model operates purely in the graph spectral domain using structured multiscale filtering, nonlinear shrinkage, and symbolic logic over wavelet coefficients. Signals defined on graph nodes are decomposed via GLWT, modulated with interpretable nonlinearities, and recombined for downstream tasks such as denoising and token classification. The system supports compositional reasoning through a symbolic domain-specific language (DSL) over graph wavelet activations. Experiments on synthetic graph denoising and linguistic token graphs demonstrate competitive performance against lightweight GNNs with far greater transparency and efficiency. This work proposes a principled, interpretable, and resource-efficient alternative to deep neural architectures for learning on graphs.
title Beyond Neural Networks: Symbolic Reasoning over Wavelet Logic Graph Signals
topic Machine Learning
url https://arxiv.org/abs/2507.21190