非线性预测函数的边际效应

IF 2.8 3区 计算机科学 Q2 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
Christian A. Scholbeck, Giuseppe Casalicchio, Christoph Molnar, Bernd Bischl, Christian Heumann
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引用次数: 0

摘要

线性回归模型的 Beta 系数是可解释特征效应的理想形式。然而,对于广义线性模型等非线性模型,估计系数不能被解释为对预测结果的直接特征效应。因此,边际效应通常被用作特征效应的近似值,或者是预测函数的导数,或者是特征值变化导致的预测结果的前向差异。虽然边际效应在很多科学领域都得到了普遍应用,但它们尚未被采用为机器学习模型的通用模型解释方法。这可能源于边际效应的模糊性,以及边际效应无法处理黑盒模型中的非线性问题。我们引入了前向边际效应(FMEs)的统一定义,其中包括单变量和多变量,以及连续、分类和混合型特征。为了考虑预测函数的非线性,我们为前向边际效应引入了非线性度量。此外,我们反对用平均边际效应等单一指标来概括非线性预测函数的特征效应。相反,我们建议在人群子群中平均同质的 FMEs,作为条件特征效应估计值。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Marginal effects for non-linear prediction functions

Marginal effects for non-linear prediction functions

Beta coefficients for linear regression models represent the ideal form of an interpretable feature effect. However, for non-linear models such as generalized linear models, the estimated coefficients cannot be interpreted as a direct feature effect on the predicted outcome. Hence, marginal effects are typically used as approximations for feature effects, either as derivatives of the prediction function or forward differences in prediction due to changes in feature values. While marginal effects are commonly used in many scientific fields, they have not yet been adopted as a general model-agnostic interpretation method for machine learning models. This may stem from the ambiguity surrounding marginal effects and their inability to deal with the non-linearities found in black box models. We introduce a unified definition of forward marginal effects (FMEs) that includes univariate and multivariate, as well as continuous, categorical, and mixed-type features. To account for the non-linearity of prediction functions, we introduce a non-linearity measure for FMEs. Furthermore, we argue against summarizing feature effects of a non-linear prediction function in a single metric such as the average marginal effect. Instead, we propose to average homogeneous FMEs within population subgroups, which serve as conditional feature effect estimates.

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来源期刊
Data Mining and Knowledge Discovery
Data Mining and Knowledge Discovery 工程技术-计算机:人工智能
CiteScore
10.40
自引率
4.20%
发文量
68
审稿时长
10 months
期刊介绍: Advances in data gathering, storage, and distribution have created a need for computational tools and techniques to aid in data analysis. Data Mining and Knowledge Discovery in Databases (KDD) is a rapidly growing area of research and application that builds on techniques and theories from many fields, including statistics, databases, pattern recognition and learning, data visualization, uncertainty modelling, data warehousing and OLAP, optimization, and high performance computing.
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