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Bibliographic Details
Main Author: Morales, Roberto
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.00185
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author Morales, Roberto
author_facet Morales, Roberto
contents This article establishes a rigorous spectral framework for the mathematical analysis of SHAP values. We show that any predictive model defined on a discrete or multi-valued input space admits a generalized Fourier expansion with respect to an orthonormalisation tensor-product basis constructed under a product probability measure. Within this setting, each SHAP attribution can be represented as a linear functional of the model's Fourier coefficients. Two complementary regimes are studied. In the deterministic regime, we derive quantitative stability estimates for SHAP values under Fourier truncation, showing that the attribution map is Lipschitz continuous with respect to the distance between predictors. In the probabilistic regime, we consider neural networks in their infinite-width limit and prove convergence of SHAP values toward those induced by the corresponding Gaussian process prior, with explicit error bounds in expectation and with high probability based on concentration inequalities. We also provide a numerical experiment on a clinical unbalanced dataset to validate the theoretical findings.
format Preprint
id arxiv_https___arxiv_org_abs_2511_00185
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle SHAP values through General Fourier Representations: Theory and Applications
Morales, Roberto
Optimization and Control
Analysis of PDEs
Machine Learning
68T07, 42B10, 60G15, 65T50
This article establishes a rigorous spectral framework for the mathematical analysis of SHAP values. We show that any predictive model defined on a discrete or multi-valued input space admits a generalized Fourier expansion with respect to an orthonormalisation tensor-product basis constructed under a product probability measure. Within this setting, each SHAP attribution can be represented as a linear functional of the model's Fourier coefficients. Two complementary regimes are studied. In the deterministic regime, we derive quantitative stability estimates for SHAP values under Fourier truncation, showing that the attribution map is Lipschitz continuous with respect to the distance between predictors. In the probabilistic regime, we consider neural networks in their infinite-width limit and prove convergence of SHAP values toward those induced by the corresponding Gaussian process prior, with explicit error bounds in expectation and with high probability based on concentration inequalities. We also provide a numerical experiment on a clinical unbalanced dataset to validate the theoretical findings.
title SHAP values through General Fourier Representations: Theory and Applications
topic Optimization and Control
Analysis of PDEs
Machine Learning
68T07, 42B10, 60G15, 65T50
url https://arxiv.org/abs/2511.00185