利用量子特征学习降低数据分析的维度

Shyam R. Sihare
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摘要

为了改进数据分析和特征学习,本研究比较了量子降维(qDR)技术与经典降维技术的有效性。在这项研究中,我们在各种数据集上研究了几种量子降维技术,如量子高斯分布自适应(qGDA)、量子主成分分析(qPCA)、量子线性判别分析(qLDA)和量子 t-SNE(qt-SNE)。本研究使用的数据集包括奥利维蒂面孔、葡萄酒、乳腺癌、数字和虹膜。通过与经典 PCA(cPCA)、经典 LDA(cLDA)和经典 GDA(cGDA)等成熟的经典方法进行比较评估,并使用损失、保真度和处理时间等成熟指标,评估了这些技术的有效性。研究结果表明,当在虹膜数据集上使用 cPCA 时,它能以最低的损失和最高的保真度产生积极的结果。另一方面,量子均匀流形逼近和投影(qUMAP)在测试 Wine 数据集时表现良好,保真度高,但 ct-SNE 在测试 Digits 数据集时表现平平。Isomap 和局部线性嵌入(LLE)的功能因数据集而异。值得注意的是,LLE 在 Olivetti Faces 数据集上的损失最大,保真度最低。假设检验结果表明,在保持量子数据集相关信息方面,qDR 策略并没有明显优于经典技术。更具体地说,配对 t 检验的结果表明,在捕捉复杂模式的能力方面,cPCA 和 qPCA、cLDA 和 qLDA 以及 cGDA 和 qGDA 之间没有显著的统计学差异。根据互信息(MI)和聚类准确性的评估结果,qPCA 可能比标准化的 cPCA 能更清晰地识别模式。不过,qLDA 和 qGDA 方法与经典方法相比没有明显改善。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Dimensionality Reduction for Data Analysis With Quantum Feature Learning
To improve data analysis and feature learning, this study compares the effectiveness of quantum dimensionality reduction (qDR) techniques to classical ones. In this study, we investigate several qDR techniques on a variety of datasets such as quantum Gaussian distribution adaptation (qGDA), quantum principal component analysis (qPCA), quantum linear discriminant analysis (qLDA), and quantum t‐SNE (qt‐SNE). The Olivetti Faces, Wine, Breast Cancer, Digits, and Iris are among the datasets used in this investigation. Through comparison evaluations against well‐established classical approaches, such as classical PCA (cPCA), classical LDA (cLDA), and classical GDA (cGDA), and using well‐established metrics like loss, fidelity, and processing time, the effectiveness of these techniques is assessed. The findings show that cPCA produced positive results with the lowest loss and highest fidelity when used on the Iris dataset. On the other hand, quantum uniform manifold approximation and projection (qUMAP) performs well and shows strong fidelity when tested against the Wine dataset, but ct‐SNE shows mediocre performance against the Digits dataset. Isomap and locally linear embedding (LLE) function differently depending on the dataset. Notably, LLE showed the largest loss and lowest fidelity on the Olivetti Faces dataset. The hypothesis testing findings showed that the qDR strategies did not significantly outperform the classical techniques in terms of maintaining pertinent information from quantum datasets. More specifically, the outcomes of paired t‐tests show that when it comes to the ability to capture complex patterns, there are no statistically significant differences between the cPCA and qPCA, the cLDA and qLDA, and the cGDA and qGDA. According to the findings of the assessments of mutual information (MI) and clustering accuracy, qPCA may be able to recognize patterns more clearly than standardized cPCA. Nevertheless, there is no discernible improvement between the qLDA and qGDA approaches and their classical counterparts.
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