Formal Riemannian Structure of the Wasserstein metric: Difference between revisions
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==Tangent Space Induced by the Wasserstein Metric== | ==Tangent Space Induced by the Wasserstein Metric== | ||
A convenient way to formalize tangent vectors in this setting is to consider time derivatives of curves on the manifold. A tangent vector at a point <math> p </math> would be the time derivative at 0 of a curve, <math> p(t) </math>, where <math> p(0) = p </math>. | |||
==Riemannian Metric Induced by the Wasserstein Metric== | ==Riemannian Metric Induced by the Wasserstein Metric== |
Revision as of 12:29, 10 June 2020
Given a closed and convex space , two probability measures on the same space, , the 2-Wasserstein metric is defined as
where is a transport plan from to . The Wasserstein metric is indeed a metric in the sense that it satisfies the desired properties of a distance function between probability measures on . Moreover, the Wasserstein metric can be used to define a Riemannian metric on . Such a metric allows one to define angles and lengths of vectors at each point in our ambient space.
Tangent Space Induced by the Wasserstein Metric
A convenient way to formalize tangent vectors in this setting is to consider time derivatives of curves on the manifold. A tangent vector at a point would be the time derivative at 0 of a curve, , where .
Riemannian Metric Induced by the Wasserstein Metric
References
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