Hoeffding decomposition of functions of random dependent variables

IF 1.4 3区数学 Q2 STATISTICS & PROBABILITY

Journal of Multivariate Analysis Pub Date : 2025-04-02 DOI:10.1016/j.jmva.2025.105444

Marouane Il Idrissi , Nicolas Bousquet , Fabrice Gamboa , Bertrand Iooss , Jean-Michel Loubes

引用次数: 0

Abstract

Hoeffding’s functional decomposition is the cornerstone of many post-hoc interpretability methods. It entails decomposing arbitrary functions of mutually independent random variables as a sum of interactions. Many generalizations to dependent covariables have been proposed throughout the years, which rely on finding a set of suitable projectors. This paper characterizes such projectors under hierarchical orthogonality constraints and mild assumptions on the variable’s probabilistic structure. Our approach is deeply rooted in Hilbert space theory, giving intuitive insights on defining, identifying, and separating interactions from the effects due to the variables’ dependence structure. This new decomposition is then leveraged to define a new functional analysis of variance. Toy cases of functions of bivariate Bernoulli and Gaussian random variables are studied.

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随机因变量函数的Hoeffding分解

Hoeffding的功能分解是许多事后可解释性方法的基石。它需要将相互独立的随机变量的任意函数分解为相互作用的总和。多年来，已经提出了许多关于相关协变量的推广，这些推广依赖于找到一组合适的投影。本文在层次正交性约束和对变量概率结构的温和假设下，对这类投影进行了刻画。我们的方法深深植根于希尔伯特空间理论，在定义、识别和分离由于变量依赖结构而产生的相互作用方面提供了直观的见解。然后利用这个新的分解来定义方差的新的功能分析。研究了二元伯努利和高斯随机变量函数的典型情况。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Multivariate Analysis 数学-统计学与概率论

CiteScore

2.40

自引率

25.00%

发文量

108

审稿时长

74 days

期刊介绍： Founded in 1971, the Journal of Multivariate Analysis (JMVA) is the central venue for the publication of new, relevant methodology and particularly innovative applications pertaining to the analysis and interpretation of multidimensional data. The journal welcomes contributions to all aspects of multivariate data analysis and modeling, including cluster analysis, discriminant analysis, factor analysis, and multidimensional continuous or discrete distribution theory. Topics of current interest include, but are not limited to, inferential aspects of Copula modeling Functional data analysis Graphical modeling High-dimensional data analysis Image analysis Multivariate extreme-value theory Sparse modeling Spatial statistics.