Gradient-based explanation for non-linear non-parametric dimensionality reduction

IF 2.8 3区计算机科学 Q2 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Data Mining and Knowledge Discovery Pub Date : 2024-07-11 DOI:10.1007/s10618-024-01055-6

Sacha Corbugy, Rebecca Marion, Benoît Frénay

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引用次数: 0

Abstract

Dimensionality reduction (DR) is a popular technique that shows great results to analyze high-dimensional data. Generally, DR is used to produce visualizations in 2 or 3 dimensions. While it can help understanding correlations between data, embeddings generated by DR are hard to grasp. The position of instances in low-dimension may be difficult to interpret, especially for non-linear, non-parametric DR techniques. Because most of the techniques are said to be neighborhood preserving (which means that explaining long distances is not relevant), some approaches try explaining them locally. These methods use simpler interpretable models to approximate the decision frontier locally. This can lead to misleading explanations. In this paper a novel approach to locally explain non-linear, non-parametric DR embeddings like t-SNE is introduced. It is the first gradient-based method for explaining these DR algorithms. The technique presented in this paper is applied on t-SNE, but is theoretically suitable for any DR method that is a minimization or maximization problem. The approach uses the analytical derivative of a t-SNE embedding to explain the position of an instance in the visualization.

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基于梯度的非线性非参数降维解释

降维（DR）是一种流行的技术，在分析高维数据方面效果显著。一般来说，降维技术用于生成 2 维或 3 维的可视化数据。虽然降维有助于理解数据之间的相关性，但降维生成的嵌入却很难把握。低维实例的位置可能难以解释，特别是对于非线性、非参数 DR 技术而言。由于大多数技术都是邻域保留技术（这意味着解释长距离并不重要），因此有些方法会尝试在本地对其进行解释。这些方法使用较简单的可解释模型来局部近似决策前沿。这可能会导致误导性解释。本文介绍了一种局部解释非线性、非参数 DR 嵌入（如 t-SNE）的新方法。这是解释这些 DR 算法的第一种基于梯度的方法。本文介绍的技术适用于 t-SNE，但理论上适用于任何 DR 方法，即最小化或最大化问题。该方法使用 t-SNE 嵌入的分析导数来解释实例在可视化中的位置。

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

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

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.