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Autores principales: Alonso, Fernando, Leitao, Álvaro, Vázquez, Carlos
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2510.19494
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author Alonso, Fernando
Leitao, Álvaro
Vázquez, Carlos
author_facet Alonso, Fernando
Leitao, Álvaro
Vázquez, Carlos
contents The ongoing progress in quantum technologies has fueled a sustained exploration of their potential applications across various domains. One particularly promising field is quantitative finance, where a central challenge is the pricing of financial derivatives-traditionally addressed through Monte Carlo integration techniques. In this work, we introduce two hybrid classical-quantum methods to address the option pricing problem. These approaches rely on reconstructing Fourier series representations of statistical distributions from the outputs of Quantum Machine Learning (QML) models based on Parametrized Quantum Circuits (PQCs). We analyze the impact of data size and PQC dimensionality on performance. Quantum Accelerated Monte Carlo (QAMC) is employed as a benchmark to quantitatively assess the proposed models in terms of computational cost and accuracy in the extraction of Fourier coefficients. Through the numerical experiments, we show that the proposed methods achieve remarkable accuracy, becoming a competitive quantum alternative for derivatives valuation.
format Preprint
id arxiv_https___arxiv_org_abs_2510_19494
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Quantum Machine Learning methods for Fourier-based distribution estimation with application in option pricing
Alonso, Fernando
Leitao, Álvaro
Vázquez, Carlos
Quantum Physics
Representation Theory
Computational Finance
65C05, 65R20, 42A10, 81P68
The ongoing progress in quantum technologies has fueled a sustained exploration of their potential applications across various domains. One particularly promising field is quantitative finance, where a central challenge is the pricing of financial derivatives-traditionally addressed through Monte Carlo integration techniques. In this work, we introduce two hybrid classical-quantum methods to address the option pricing problem. These approaches rely on reconstructing Fourier series representations of statistical distributions from the outputs of Quantum Machine Learning (QML) models based on Parametrized Quantum Circuits (PQCs). We analyze the impact of data size and PQC dimensionality on performance. Quantum Accelerated Monte Carlo (QAMC) is employed as a benchmark to quantitatively assess the proposed models in terms of computational cost and accuracy in the extraction of Fourier coefficients. Through the numerical experiments, we show that the proposed methods achieve remarkable accuracy, becoming a competitive quantum alternative for derivatives valuation.
title Quantum Machine Learning methods for Fourier-based distribution estimation with application in option pricing
topic Quantum Physics
Representation Theory
Computational Finance
65C05, 65R20, 42A10, 81P68
url https://arxiv.org/abs/2510.19494