Semidiscrete Optimal Transport: Difference between revisions

Revision as of 04:05, 3 June 2020

Semidiscrete optimal transport refers to situations in optimal transport where two input measures are considered, and one measure is a discrete measure and the other one is continuous. Hence, because only one of the two measures is discrete, we arrive at the appropriate name "semidiscrete."

Formulation of the Semidiscrete Dual Problem

In particular, we will examine semidiscrete optimal transport in the case of the dual problem. The general dual problem for continuous measures can be stated as

\max _{(\varphi ,\psi )\in R(c)}{\Big \{}\int _{X}\varphi d\mu +\int _{Y}\psi d\nu {\Big \}}

where $\mu ,\nu$ denote probability measures on domains $X,Y$ respectively, and $c(x,y)$ is a cost function defined over $X\times Y$ . $R(c)$ denotes the set of possible dual potentials, and the condition $\varphi (x)+\psi (y)\leq c(x,y)$ is satisfied. It should also be noted that $\mu =f(x)dx$ has a density. Now, we would like to extend this notion of the dual problem to the semidiscrete case. Such a case can be reformulated as

\max _{\varphi \in \mathbb {R} ^{m}}{\Big \{}\int _{X}\varphi ^{c}d\mu +\sum _{j}\varphi _{j}b_{j}{\Big \}}.

Aside from using a discrete measure in place of what was originally a continuous one, there are a few other notable distinctions within this reformulation. The first is that $\psi$ is replaced completely with $\varphi$ . The second is that $\varphi ^{c}$ denotes the c-transform of $\varphi$ . The c-transform can be defined as $\varphi ^{c}(x):=\min _{j}\{c(x,y_{j})-\varphi _{j}\}$ .

Voronoi Cells

Now, we will establish the notion of Voronoi cells. The Voronoi cells refer to a special subset of $X$ , and the reason we are interested in such a subset is because we can use the Voronoi cells as a domain to find the weights $b_{j}$ that we established in our reformulation of the dual problem. In particular, if we denote the set of Voronoi cells as $V_{\varphi }(j)$ , we can find our weights using the fact $b_{j}=\int _{V_{\varphi }(j)}f(x)dx$

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	== Voronoi Cells ==		== Voronoi Cells ==

	Now, we will establish the notion of Voronoi cells. The Voronoi cells refer to a special subset of <math> X </math>, and the reason we are interested in such a subset is because we can use the Voronoi cells as a domain to find the weights <math> b_j </math> that we established in our reformulation of the dual problem. In particular, if we denote the set of Voronoi cells as <math> V_{\varphi}(j) </math>,		Now, we will establish the notion of Voronoi cells. The Voronoi cells refer to a special subset of <math> X </math>, and the reason we are interested in such a subset is because we can use the Voronoi cells as a domain to find the weights <math> b_j </math> that we established in our reformulation of the dual problem. In particular, if we denote the set of Voronoi cells as <math> V_{\varphi}(j) </math>, we can find our weights using the fact <math> b_j = \int_{V_{\varphi}(j)} f(x)dx </math>

Semidiscrete Optimal Transport: Difference between revisions

Revision as of 04:05, 3 June 2020

Formulation of the Semidiscrete Dual Problem

Voronoi Cells

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