Pathwise CVA Regressions With Oversimulated Defaults
Abstract
We consider the computation by simulation and neural net regression of conditional expectations, or more general elicitable statistics, of functionals of processes . Here an exogenous component (Markov by itself) is time-consuming to simulate, while the endogenous component (jointly Markov with ) is quick to simulate given , but is responsible for most of the variance of the simulated payoff. To address the related variance issue, we introduce a conditionally independent, hierarchical simulation scheme, where several paths of are simulated for each simulated path of . We analyze the statistical convergence of the regression learning scheme based on such block-dependent data. We derive heuristics on the number of paths of and, for each of them, of , that should be simulated. The resulting algorithm is implemented on a graphics processing unit (GPU) combining Python/CUDA and learning with PyTorch. A CVA case study with a nested Monte Carlo benchmark shows that the hierarchical simulation technique is key to the success of the learning approach.
Cite
@article{arxiv.2211.17005,
title = {Pathwise CVA Regressions With Oversimulated Defaults},
author = {Lokman Abbas-Turki and Stéphane Crépey and Bouazza Saadeddine},
journal= {arXiv preprint arXiv:2211.17005},
year = {2022}
}
Comments
This article has been accepted for publication in Mathematical Finance, published by Wiley