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Main Authors: Ferrere, Baptiste, Bousquet, Nicolas, Gamboa, Fabrice, Loubes, Jean-Michel
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.18422
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author Ferrere, Baptiste
Bousquet, Nicolas
Gamboa, Fabrice
Loubes, Jean-Michel
author_facet Ferrere, Baptiste
Bousquet, Nicolas
Gamboa, Fabrice
Loubes, Jean-Michel
contents The functional ANOVA, or Hoeffding decomposition, provides a principled framework for interpretability by decomposing a model prediction into main effects and higher-order interactions. For independent inputs, this classical decomposition is explicit. It is closely connected to SHAP values, generalized additive models, and orthogonal polynomial expansions, and therefore constitutes a fundamental tool for additive explainability. In the more general and realistic dependent setting, however, obtaining a tractable representation and estimating the decomposition from data remain challenging. In this work, we address this problem for continuous inputs. By combining Hilbert space methods with the generalized functional ANOVA, we build an explicit decomposition Riesz Basis allowing to easily compute the decomposition. Our formulation recovers the classical independent case and its associated orthogonal decomposition. Building on this representation, we propose a simple but mighty algorithm to estimate the decomposition from a data sample in a model-agnostic setting and we compare it empirically with several state-of-the-art explanation methods, demonstrating the power of the approach.
format Preprint
id arxiv_https___arxiv_org_abs_2605_18422
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Generalized Functional ANOVA in Closed-Form: A Unified View of Additive Explanations
Ferrere, Baptiste
Bousquet, Nicolas
Gamboa, Fabrice
Loubes, Jean-Michel
Machine Learning
Statistics Theory
62J10 (Primary), 62G05, 68T05, 42C15, 33C45 (Secondary)
The functional ANOVA, or Hoeffding decomposition, provides a principled framework for interpretability by decomposing a model prediction into main effects and higher-order interactions. For independent inputs, this classical decomposition is explicit. It is closely connected to SHAP values, generalized additive models, and orthogonal polynomial expansions, and therefore constitutes a fundamental tool for additive explainability. In the more general and realistic dependent setting, however, obtaining a tractable representation and estimating the decomposition from data remain challenging. In this work, we address this problem for continuous inputs. By combining Hilbert space methods with the generalized functional ANOVA, we build an explicit decomposition Riesz Basis allowing to easily compute the decomposition. Our formulation recovers the classical independent case and its associated orthogonal decomposition. Building on this representation, we propose a simple but mighty algorithm to estimate the decomposition from a data sample in a model-agnostic setting and we compare it empirically with several state-of-the-art explanation methods, demonstrating the power of the approach.
title Generalized Functional ANOVA in Closed-Form: A Unified View of Additive Explanations
topic Machine Learning
Statistics Theory
62J10 (Primary), 62G05, 68T05, 42C15, 33C45 (Secondary)
url https://arxiv.org/abs/2605.18422