expository stuff to be filled in
Motivation
When the quadratic Wasserstein and distance become asymptotically equivalent when the involved densities are close to . This is particularly of interest in evolution problems with a constraint of such as crowd motion. [1]
Formalization
Lemma
Let be absolutely continuous measures on a convex domain , with densities bounded by the same constant . Then, for all functions :
Proof of the lemma can be found Chapter 5, page 210 of [1].
Definition of
The negative Sobolev norm is defined [1] [2] to be
Theorem
Let be absolutely continuous measures on a convex domain , with densities bounded from below and from above by the same constants with . Then
The proof of the theorem uses the above lemma and can be found Chapter 5, page 211 of [1].
Application to Localization
The following material is adapted from [2].
This section deals with the problem of localization of the quadratic Wasserstein distance: if are measures on that are close in the sense of , do they remain close to each other when restricted to subsets of ?
Notation
Here we are working in Euclidean space whose norm will be denoted by . When necessary, the Lebesgue measure on will be denoted by .
- Recall that for a subset ,
denotes the distance between a point and the subset .
- For a measure on and a nonnegative and measurable function, denotes the measure such that .
- The norm
denotes the total variation norm of the measure .
- For a measure supported on , define the norm
Theorem
Let be measures on having the same total mass, and let be a ball in . Assume that on , the density of with respect to the Lebesgue measure is bounded above and below, that is
Let be a -Lipschitz function for some supported in , and suppose that is bounded above and below by the map on , that is, there exists constants such that for all ,
Then, denoting ,
for some absolute constant depending only on . Moreover, taking fits. [2]
References