Designing universal causal deep learning models: The geometric (Hyper)transformer

IF 1.6 3区 经济学 Q3 BUSINESS, FINANCE Mathematical Finance Pub Date : 2023-04-26 DOI:10.1111/mafi.12389
Beatrice Acciaio, Anastasis Kratsios, Gudmund Pammer
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Abstract

Several problems in stochastic analysis are defined through their geometry, and preserving that geometric structure is essential to generating meaningful predictions. Nevertheless, how to design principled deep learning (DL) models capable of encoding these geometric structures remains largely unknown. We address this open problem by introducing a universal causal geometric DL framework in which the user specifies a suitable pair of metric spaces X $\mathcal {X}$ and Y $\mathcal {Y}$ and our framework returns a DL model capable of causally approximating any “regular” map sending time series in X Z $\mathcal {X}^{\mathbb {Z}}$ to time series in Y Z $\mathcal {Y}^{\mathbb {Z}}$ while respecting their forward flow of information throughout time. Suitable geometries on Y $\mathcal {Y}$ include various (adapted) Wasserstein spaces arising in optimal stopping problems, a variety of statistical manifolds describing the conditional distribution of continuous-time finite state Markov chains, and all Fréchet spaces admitting a Schauder basis, for example, as in classical finance. Suitable spaces X $\mathcal {X}$ are compact subsets of any Euclidean space. Our results all quantitatively express the number of parameters needed for our DL model to achieve a given approximation error as a function of the target map's regularity and the geometric structure both of X $\mathcal {X}$ and of Y $\mathcal {Y}$ . Even when omitting any temporal structure, our universal approximation theorems are the first guarantees that Hölder functions, defined between such X $\mathcal {X}$ and Y $\mathcal {Y}$ can be approximated by DL models.

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设计通用因果深度学习模型:几何(超级)变压器
随机分析中的几个问题是通过它们的几何结构来定义的,保持几何结构对于产生有意义的预测是必不可少的。然而,如何设计能够编码这些几何结构的原则性深度学习(DL)模型在很大程度上仍然未知。我们通过引入一个通用的因果几何深度学习框架来解决这个开放问题,在这个框架中,用户指定一对合适的度量空间$\mathscr{X}$和$\mathscr{Y}$,我们的框架返回一个深度学习模型,该模型能够将$\mathscr{X}^{\mathbb{Z}}$中的任何“规则”映射因果地逼近$\mathscr{Y}}^{\mathbb{Z}}$中的时间序列发送到$\mathscr{Y}}}$中的时间序列,同时尊重它们在整个时间中的前向信息流。$\mathscr{Y}$上的合适几何包括在最优停止问题中产生的各种(适应的)Wasserstein空间,描述连续时间有限状态马尔可夫链的条件分布的各种统计流形,以及允许Schauder基的所有Fr\ {e}chet空间,例如在经典金融中。合适的空间$\mathscr{X}$是任何欧几里德空间的紧子集。我们的结果都定量地表达了我们的DL模型所需的参数数量,以实现给定的近似误差,作为目标映射的正则性和$\mathscr{X}$和$\mathscr{Y}$的几何结构的函数。即使省略了任何时间结构,我们的普遍近似定理也第一次保证了在$\mathscr{X}$和$\mathscr{Y}$之间定义的H\ \ 0}阶函数可以被DL模型近似。
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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来源期刊
Mathematical Finance
Mathematical Finance 数学-数学跨学科应用
CiteScore
4.10
自引率
6.20%
发文量
27
审稿时长
>12 weeks
期刊介绍: Mathematical Finance seeks to publish original research articles focused on the development and application of novel mathematical and statistical methods for the analysis of financial problems. The journal welcomes contributions on new statistical methods for the analysis of financial problems. Empirical results will be appropriate to the extent that they illustrate a statistical technique, validate a model or provide insight into a financial problem. Papers whose main contribution rests on empirical results derived with standard approaches will not be considered.
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