Fluctuation Identities with Continuous Monitoring and Their Application to Price Barrier Options

Mathematics eJournal Pub Date : 2017-11-30 DOI:10.2139/ssrn.3080495

Carolyn E. Phelan, D. Marazzina, Gianluca Fusai, G. Germano

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引用次数: 3

Abstract

We present a numerical scheme to calculate fluctuation identities for exponential L\'evy processes in the continuous monitoring case. This includes the Spitzer identities for touching a single upper or lower barrier, and the more difficult case of the two-barriers exit problem. These identities are given in the Fourier-Laplace domain and require numerical inverse transforms. Thus we cover a gap in the literature that has mainly studied the discrete monitoring case; indeed, there are no existing numerical methods that deal with the continuous case. As a motivating application we price continuously monitored barrier options with the underlying asset modelled by an exponential L\'evy process. We perform a detailed error analysis of the method and develop error bounds to show how the performance is limited by the truncation error of the sinc-based fast Hilbert transform used for the Wiener-Hopf factorisation. By comparing the results for our new technique with those for the discretely monitored case (which is in the Fourier-$z$ domain) as the monitoring time step approaches zero, we show that the error convergence with continuous monitoring represents a limit for the discretely monitored scheme.

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连续监测的波动恒等式及其在价格障碍期权中的应用

在连续监测情况下，我们给出了一种计算指数L′evy过程波动恒等式的数值格式。这包括斯皮策恒等式涉及到一个单一的上或下势垒，以及更困难的双势垒出口问题。这些恒等式是在傅里叶-拉普拉斯域中给出的，需要数值逆变换。因此，我们填补了主要研究离散监测案例的文献中的空白;事实上，目前还没有处理连续情况的数值方法。作为一种激励应用，我们对持续监控的障碍期权进行定价，其基础资产由指数L\ \ every过程建模。我们对该方法进行了详细的误差分析，并制定了误差界限，以显示性能如何受到用于Wiener-Hopf分解的基于自适应的快速希尔伯特变换的截断误差的限制。通过将我们的新技术的结果与当监测时间步长趋近于零时的离散监测情况(在傅里叶-$z$域中)的结果进行比较，我们表明连续监测的误差收敛代表了离散监测方案的极限。

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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Mathematics eJournal

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