用广义几何散射变换理解图神经网络

IF 1.9 Q1 MATHEMATICS, APPLIED
Michael Perlmutter, Alexander Tong, Feng Gao, Guy Wolf, Matthew Hirn
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引用次数: 2

摘要

散射变换是一种多层基于小波的结构,作为卷积神经网络的模型。近年来,一些研究工作将散射变换推广到图结构数据。我们的工作建立在这些结构的基础上,通过引入基于两种非常一般的小波的图形的有窗和无窗几何散射变换,这两种小波在大多数情况下是基于非对称矩阵的。我们证明这些变换与它们的对称对应物有许多相同的理论保证。因此,所提出的结构统一并扩展了许多现有图散射结构的已知理论结果。因此,它通过引入大量具有可证明的稳定性和不变性保证的网络,有助于弥合几何散射与其他图神经网络之间的差距。这些结果为具有学习过滤器的图结构数据的未来深度学习架构奠定了基础,并且也被证明具有理想的理论性质。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Understanding Graph Neural Networks with Generalized Geometric Scattering Transforms
The scattering transform is a multilayered wavelet-based architecture that acts as a model of convolutional neural networks. Recently, several works have generalized the scattering transform to graph-structured data. Our work builds on these constructions by introducing windowed and nonwindowed geometric scattering transforms for graphs based on two very general classes wavelets, which are in most cases based on asymmetric matrices. We show that these transforms have many of the same theoretical guarantees as their symmetric counterparts. As a result, the proposed construction unifies and extends known theoretical results for many of the existing graph scattering architectures. Therefore, it helps bridge the gap between geometric scattering and other graph neural networks by introducing a large family of networks with provable stability and invariance guarantees. These results lay the groundwork for future deep learning architectures for graph-structured data that have learned filters and also provably have desirable theoretical properties.
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