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Auteur principal: Kiruluta, Andrew
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2507.19514
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author Kiruluta, Andrew
author_facet Kiruluta, Andrew
contents We introduce a fully spectral learning framework that eliminates traditional neural layers by operating entirely in the wavelet domain. The model applies learnable nonlinear transformations, including soft-thresholding and gain-phase modulation, directly to wavelet coefficients. It also includes a differentiable wavelet basis selection mechanism, enabling adaptive processing using families such as Haar, Daubechies, and Biorthogonal wavelets. Implemented in PyTorch with full 3D support, the model maintains a spectral pipeline without spatial convolutions or attention. On synthetic 3D denoising and natural language tasks from the GLUE benchmark, including SST-2 sentiment classification, the model achieves 89.3 percent accuracy, close to a 4-layer Transformer baseline (90.1 percent), while using 72 percent fewer parameters and 58 percent less peak memory. Faster early convergence is observed due to spectral sparsity priors. In contrast to the quadratic complexity of self-attention and large matrix multiplications in Transformers, our approach uses linear-time wavelet transforms and pointwise nonlinearities, significantly reducing inference cost. This yields a compact, interpretable, and efficient alternative to neural models. Our results support the viability of principled spectral learning in both vision and language tasks, offering new directions for model design without overparameterized architectures.
format Preprint
id arxiv_https___arxiv_org_abs_2507_19514
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Wavelet Logic Machines: Learning and Reasoning in the Spectral Domain Without Neural Networks
Kiruluta, Andrew
Machine Learning
We introduce a fully spectral learning framework that eliminates traditional neural layers by operating entirely in the wavelet domain. The model applies learnable nonlinear transformations, including soft-thresholding and gain-phase modulation, directly to wavelet coefficients. It also includes a differentiable wavelet basis selection mechanism, enabling adaptive processing using families such as Haar, Daubechies, and Biorthogonal wavelets. Implemented in PyTorch with full 3D support, the model maintains a spectral pipeline without spatial convolutions or attention. On synthetic 3D denoising and natural language tasks from the GLUE benchmark, including SST-2 sentiment classification, the model achieves 89.3 percent accuracy, close to a 4-layer Transformer baseline (90.1 percent), while using 72 percent fewer parameters and 58 percent less peak memory. Faster early convergence is observed due to spectral sparsity priors. In contrast to the quadratic complexity of self-attention and large matrix multiplications in Transformers, our approach uses linear-time wavelet transforms and pointwise nonlinearities, significantly reducing inference cost. This yields a compact, interpretable, and efficient alternative to neural models. Our results support the viability of principled spectral learning in both vision and language tasks, offering new directions for model design without overparameterized architectures.
title Wavelet Logic Machines: Learning and Reasoning in the Spectral Domain Without Neural Networks
topic Machine Learning
url https://arxiv.org/abs/2507.19514