Shadow martingales -- a stochastic mass transport approach to the peacock problem

Abstract

Given a family of real probability measures (μt)t≥ 0 increasing in convex order (a peacock) we describe a systematic method to create a martingale exactly fitting the marginals at any time. The key object for our approach is the obstructed shadow of a measure in a peacock, a generalization of the (obstructed) shadow introduced in BeJu16,NuStTa17. As input data we take an increasing family of measures (α)α ∈ [0,1] with α(R)=α that are submeasures of μ 0, called a parametrization of μ0. Then, for any α we define an evolution (ηαt)t≥ 0 of the measure α=ηα0 across our peacock by setting ηαt equal to the obstructed shadow of α in (μ s)s ∈ [0,t]. We identify conditions on the parametrization (α)α∈ [0,1] such that this construction leads to a unique martingale measure π, the shadow martingale, without any assumptions on the peacock. In the case of the left-curtain parametrization (lcα)α ∈ [0,1] we identify the shadow martingale as the unique solution to a continuous-time version of the martingale optimal transport problem. Furthermore, our method enriches the knowledge on the Predictable Representation Property (PRP) since any shadow martingale comes with a canonical Choquet representation in extremal Markov martingales.