Shreya Arya, Arnab Auddy, Ranthony A. Clark, Sunhyuk Lim, Facundo Mémoli, Daniel Packer
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引用次数: 0
摘要
格罗莫夫-瓦瑟斯坦距离--通常的瓦瑟斯坦距离的广义化--允许比较定义在可能不同的度量空间上的概率度量。最近,这一距离概念在数据科学和机器学习中得到了广泛应用。为了帮助解释通过格罗莫夫-瓦瑟斯坦距离计算出的不相似度量,并评估旨在估算格罗莫夫-瓦瑟斯坦距离的计算技术的近似质量,我们确定了不同维度的单位球之间格罗莫夫-瓦瑟斯坦距离的某个变体的精确值。事实上,我们考虑的是度量空间之间的格罗莫夫-瓦瑟斯坦距离的双参数族((\{d_{{text {GW}}}p,q}\}_{p,q=1}^{\infty }\ )。通过利用参数 p 和 q 的特定值与底层空间度量之间的相互作用,我们能够确定所有不同维度的单位球之间的距离 \(d_{{text{GW}}4,2}\)的精确值。
The Gromov–Wasserstein distance—a generalization of the usual Wasserstein distance—permits comparing probability measures defined on possibly different metric spaces. Recently, this notion of distance has found several applications in Data Science and in Machine Learning. With the goal of aiding both the interpretability of dissimilarity measures computed through the Gromov–Wasserstein distance and the assessment of the approximation quality of computational techniques designed to estimate the Gromov–Wasserstein distance, we determine the precise value of a certain variant of the Gromov–Wasserstein distance between unit spheres of different dimensions. Indeed, we consider a two-parameter family \(\{d_{{{\text {GW}}}p,q}\}_{p,q=1}^{\infty }\) of Gromov–Wasserstein distances between metric measure spaces. By exploiting a suitable interaction between specific values of the parameters p and q and the metric of the underlying spaces, we are able to determine the exact value of the distance \(d_{{{\text {GW}}}4,2}\) between all pairs of unit spheres of different dimensions endowed with their Euclidean distance and their uniform measure.
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