一个用于监督张量学习的对偶结构保持核及其在神经图像中的应用。

Lifang He, Xiangnan Kong, Philip S Yu, Ann B Ragin, Zhifeng Hao, Xiaowei Yang
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引用次数: 74

摘要

随着数据收集技术的进步,张量数据在许多应用中越来越突出,监督张量学习问题已经成为数据挖掘和机器学习社区中一个至关重要的话题。传统的监督张量学习方法主要是通过将张量扁平化为向量或矩阵来学习核,但是会丢失张量内部的结构信息。在本文中,我们引入了一种新的方案来设计用于监督张量学习的保结构核。具体来说,我们演示了如何利用张量表示中自然可用的结构来编码内核中的先验知识。我们提出了一种基于双张量映射的张量核,可以保留张量结构。双张量映射函数可以将输入空间中的每个张量实例映射到特征空间中的另一个张量,同时保持张量结构。理论上,我们的方法是将向量空间中的常规核扩展到张量空间。我们将我们的新核与支持向量机一起应用于现实世界的张量分类问题,包括对三种不同疾病(即阿尔茨海默病、多动症和艾滋病毒引起的脑损伤)的脑功能磁共振分类。大量的实证研究表明,我们提出的方法可以有效地提高张量分类性能,特别是在小样本量的情况下。
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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DuSK: A Dual Structure-preserving Kernel for Supervised Tensor Learning with Applications to Neuroimages.

With advances in data collection technologies, tensor data is assuming increasing prominence in many applications and the problem of supervised tensor learning has emerged as a topic of critical significance in the data mining and machine learning community. Conventional methods for supervised tensor learning mainly focus on learning kernels by flattening the tensor into vectors or matrices, however structural information within the tensors will be lost. In this paper, we introduce a new scheme to design structure-preserving kernels for supervised tensor learning. Specifically, we demonstrate how to leverage the naturally available structure within the tensorial representation to encode prior knowledge in the kernel. We proposed a tensor kernel that can preserve tensor structures based upon dual-tensorial mapping. The dual-tensorial mapping function can map each tensor instance in the input space to another tensor in the feature space while preserving the tensorial structure. Theoretically, our approach is an extension of the conventional kernels in the vector space to tensor space. We applied our novel kernel in conjunction with SVM to real-world tensor classification problems including brain fMRI classification for three different diseases (i.e., Alzheimer's disease, ADHD and brain damage by HIV). Extensive empirical studies demonstrate that our proposed approach can effectively boost tensor classification performances, particularly with small sample sizes.

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