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arxiv: 1705.05951 · v2 · pith:C5PXZNJRnew · submitted 2017-05-16 · 🧮 math.AP

Optimal Ballistic Transport and Hopf-Lax Formulae on Wasserstein Space

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keywords gammaspaceballisticcostoptimaltimestransportassociated
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We investigate the optimal mass transport problem associated to the following "ballistic" cost functional on phase space $M\times M^*$, $$ b_T(v, x):=\inf\{\langle v, \gamma (0)\rangle +\int_0^TL(\gamma (t), {\dot \gamma}(t))\, dt, \gamma \in C^1([0, T), M), \gamma(T)=x\}, $$ where $M=\mathbb{R}^d$, $T>0$, and $L:M\times M \to \mathbb{R}$ is a Lagrangian that is jointly convex in both variables. Under suitable conditions on the initial and final probability measures, we use convex duality \`a la Bolza and Monge-Kantorovich theory to lift classical Hopf-Lax formulae from state space to Wasserstein space. This allows us to relate optimal transport maps for the ballistic cost to those associated with the fixed-end cost defined on $M\times M$ by $$ c_T(x,y):=\inf\{\int_0^TL(\gamma(t), {\dot \gamma}(t))\, dt, \gamma\in C^1([0, T), M), \gamma(0)=x, \gamma(T)=y\}. $$ We also point to links with the theory of mean field games.

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