Error analysis in fourier methods for option pricing

Fabián Crocce; Juho Häppölä; Jonas Kiessling; Raúl Tempone

doi:10.21314/JCF.2016.327

Error analysis in fourier methods for option pricing

Fabián Crocce, Juho Häppölä^*, Jonas Kiessling, Raúl Tempone

^*Corresponding author for this work

Applied Mathematics and Computational Science

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

We provide a bound for the error committed when using a Fourier method to price European options, when the underlying follows an exponential Lévy dynamic. The price of the option is described by a partial integro-differential equation (PIDE). Applying a Fourier transformation to the PIDE yields an ordinary differential equation (ODE) that can be solved analytically in terms of the characteristic exponent of the Lévy process. Then, a numerical inverse Fourier transform allows us to obtain the option price. We present a bound for the error and use this bound to set the parameters for the numerical method. We analyze the properties of the bound and demonstrate the minimization of the bound to select parameters for a numerical Fourier transformation method in order to solve the option price efficiently.

Original language	English (US)
Pages (from-to)	53-82
Number of pages	30
Journal	Journal of Computational Finance
Volume	21
Issue number	1
DOIs	https://doi.org/10.21314/JCF.2016.327
State	Published - Jun 2017

Keywords

Error analysis
European options
Fourier methods
Lévy processes
Trapezoid quadrature

ASJC Scopus subject areas

Finance
Computer Science Applications
Applied Mathematics

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10.21314/JCF.2016.327

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abstract = "We provide a bound for the error committed when using a Fourier method to price European options, when the underlying follows an exponential L{\'e}vy dynamic. The price of the option is described by a partial integro-differential equation (PIDE). Applying a Fourier transformation to the PIDE yields an ordinary differential equation (ODE) that can be solved analytically in terms of the characteristic exponent of the L{\'e}vy process. Then, a numerical inverse Fourier transform allows us to obtain the option price. We present a bound for the error and use this bound to set the parameters for the numerical method. We analyze the properties of the bound and demonstrate the minimization of the bound to select parameters for a numerical Fourier transformation method in order to solve the option price efficiently.",

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author = "Fabi{\'a}n Crocce and Juho H{\"a}pp{\"o}l{\"a} and Jonas Kiessling and Ra{\'u}l Tempone",

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year = "2017",

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AU - Crocce, Fabián

AU - Häppölä, Juho

AU - Kiessling, Jonas

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AB - We provide a bound for the error committed when using a Fourier method to price European options, when the underlying follows an exponential Lévy dynamic. The price of the option is described by a partial integro-differential equation (PIDE). Applying a Fourier transformation to the PIDE yields an ordinary differential equation (ODE) that can be solved analytically in terms of the characteristic exponent of the Lévy process. Then, a numerical inverse Fourier transform allows us to obtain the option price. We present a bound for the error and use this bound to set the parameters for the numerical method. We analyze the properties of the bound and demonstrate the minimization of the bound to select parameters for a numerical Fourier transformation method in order to solve the option price efficiently.

KW - Error analysis

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Error analysis in fourier methods for option pricing

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