Disentangling Interpretable Factors with Supervised Independent Subspace Principal Component Analysis.

ArXiv Pub Date : 2024-10-31
Jiayu Su, David A Knowles, Raul Rabadan
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Abstract

The success of machine learning models relies heavily on effectively representing high-dimensional data. However, ensuring data representations capture human-understandable concepts remains difficult, often requiring the incorporation of prior knowledge and decomposition of data into multiple subspaces. Traditional linear methods fall short in modeling more than one space, while more expressive deep learning approaches lack interpretability. Here, we introduce Supervised Independent Subspace Principal Component Analysis ($\texttt{sisPCA}$), a PCA extension designed for multi-subspace learning. Leveraging the Hilbert-Schmidt Independence Criterion (HSIC), $\texttt{sisPCA}$ incorporates supervision and simultaneously ensures subspace disentanglement. We demonstrate $\texttt{sisPCA}$'s connections with autoencoders and regularized linear regression and showcase its ability to identify and separate hidden data structures through extensive applications, including breast cancer diagnosis from image features, learning aging-associated DNA methylation changes, and single-cell analysis of malaria infection. Our results reveal distinct functional pathways associated with malaria colonization, underscoring the essentiality of explainable representation in high-dimensional data analysis.

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用监督独立子空间主成分分析法分解可解释因素
机器学习模型的成功在很大程度上依赖于有效地表示高维数据。然而,确保数据表示捕捉人类可理解的概念仍然很困难,通常需要结合先验知识并将数据分解为多个子空间。传统的线性方法无法为多个空间建模,而更具表现力的深度学习方法则缺乏可解释性。在这里,我们引入了监督独立子空间主成分分析(Supervised Independent Subspace Principal Component Analysis,$texttt{sisPCA}$),这是一种专为多子空间学习而设计的 PCA 扩展。利用希尔伯特-施密特独立准则(Hilbert-Schmidt Independence Criterion,HSIC),$texttt{sisPCA}$结合了监督并同时确保子空间不纠缠。我们展示了$texttt{sisPCA}$与自动编码器和正则化线性回归的联系,并通过广泛的应用展示了其识别和分离隐藏数据结构的能力,包括从图像特征诊断乳腺癌、学习衰老相关的DNA甲基化变化以及疟疾感染的单细胞分析。我们的研究结果揭示了与疟疾定植相关的不同功能途径,强调了可解释表征在高维数据分析中的重要性。
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