Geometric Martingale Benamou-Brenier transport and geometric Bass martingales

arXiv - QuantFin - Mathematical Finance Pub Date : 2024-06-06 DOI:arxiv-2406.04016

Julio Backhoff-Veraguas, Gregoire Loeper, Jan Obloj

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引用次数: 0

Abstract

We introduce and study geometric Bass martingales. Bass martingales were introduced in \cite{Ba83} and studied recently in a series of works, including \cite{BaBeHuKa20,BaBeScTs23}, where they appear as solutions to the martingale version of the Benamou-Brenier optimal transport formulation. These arithmetic, as well as our novel geometric, Bass martingales are continuous martingale on $[0,1]$ with prescribed initial and terminal distributions. An arithmetic Bass martingale is the one closest to Brownian motion: its quadratic variation is as close as possible to being linear in the averaged $L^2$ sense. Its geometric counterpart we develop here, is the one closest to a geometric Brownian motion: the quadratic variation of its logarithm is as close as possible to being linear. By analogy between Bachelier and Black-Scholes models in mathematical finance, the newly obtained geometric Bass martingales} have the potential to be of more practical importance in a number of applications. Our main contribution is to exhibit an explicit bijection between geometric Bass martingales and their arithmetic counterparts. This allows us, in particular, to translate fine properties of the latter into the new geometric setting. We obtain an explicit representation for a geometric Bass martingale for given initial and terminal marginals, we characterise it as a solution to an SDE, and we show that geometric Brownian motion is the only process which is both an arithmetic and a geometric Bass martingale. Finally, we deduce a dual formulation for our geometric martingale Benamou-Brenier problem. Our main proof is probabilistic in nature and uses a suitable change of measure, but we also provide PDE arguments relying on the dual formulation of the problem, which offer a rigorous proof under suitable regularity assumptions.

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几何马丁格尔贝纳摩-布雷尼尔输运和几何巴斯马丁格尔

我们介绍并研究几何巴斯马汀矢。Bass martingales 是在（cite{Ba83}中引入的，最近在一系列著作中进行了研究，包括（cite{BaBeHuKa20,BaBeScTs23}），在这些著作中，Bass martingales 作为贝纳穆-布雷尼尔最优输运公式的 martingaleversion 的解出现。这些算术巴斯马汀矢以及我们的新几何巴斯马汀矢都是$[0,1]$上的连续马汀矢，具有规定的初始和终结分布。算术巴斯常数是最接近布朗运动的常数：它的二次变化尽可能接近平均 $L^2$ 意义上的线性。我们在此开发的几何对应项是最接近几何布朗运动的：其对数的二次变化尽可能接近线性。通过类比数学金融中的巴切利耶模型和布莱克-斯科尔斯模型，新得到的几何巴斯马丁格尔有可能在许多应用中具有更重要的实际意义。我们的主要贡献在于展示了几何巴斯马氏模型与其算术对应模型之间的显式双射关系。这尤其使我们能够将后者的优良特性转化为新的几何设定。对于给定的初始边际和末端边际，我们得到了几何巴斯鞅的明确表示，并将其描述为一个 SDE 的解，还证明了几何布朗运动是唯一一个既是算术鞅又是几何巴斯鞅的过程。最后，我们推导出几何马汀厄贝纳穆-布雷尼尔问题的对偶形式。我们的主要证明在本质上是概率性的，并使用了适当的度量变化，但我们也提供了依赖于问题对偶形式的 PDE 论证，在适当的正则性假设下提供了严格的证明。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - QuantFin - Mathematical Finance

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