Learning parameter dependence for Fourier-based option pricing with tensor trains
Abstract
A long-standing issue in mathematical finance is the speed-up of option pricing, especially for multi-asset options. A recent study has proposed to use tensor train learning algorithms to speed up Fourier transform (FT)-based option pricing, utilizing the ability of tensor trains to compress high-dimensional tensors. Another usage of the tensor train is to compress functions, including their parameter dependence. Here, we propose a pricing method, where, by a tensor train learning algorithm, we build tensor trains that approximate functions appearing in FT-based option pricing with their parameter dependence and efficiently calculate the option price for the varying input parameters. As a benchmark test, we run the proposed method to price a multi-asset option for the various values of volatilities and present asset prices. We show that, in the tested cases involving up to 11 assets, the proposed method outperforms Monte Carlo-based option pricing with paths in terms of computational complexity while keeping better accuracy.
Cite
@article{arxiv.2405.00701,
title = {Learning parameter dependence for Fourier-based option pricing with tensor trains},
author = {Rihito Sakurai and Haruto Takahashi and Koichi Miyamoto},
journal= {arXiv preprint arXiv:2405.00701},
year = {2025}
}