在粗糙的Bergomi模型中对VIX期权进行多层蒙特卡罗模拟

IF 0.8 4区经济学 Q4 BUSINESS, FINANCE

Journal of Computational Finance Pub Date : 2021-05-11 DOI:10.21314/jcf.2022.023

Florian Bourgey, S. Marco

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引用次数: 5

摘要

我们在粗糙Bergomi模型中考虑波动率指数期权的定价。在这种设置中，VIX随机变量由具有相关增量的高斯过程的指数的一维积分定义，因此可以通过积分的离散化和相关高斯向量的模拟来构造VIX的近似样本。当均方误差设置为$\varepsilon^2$时，基于矩形离散化方案和通过Cholesky方法的精确高斯采样的VIX选项的蒙特卡罗估计器的计算复杂度为$\mathcal｛O｝（\varepsilion^｛-4｝）$阶。我们证明，将上述方案与多级方法相结合，该成本可以降低到$\mathcal｛O｝（\varepsilon ^｛-2｝\log^2（\varepilon））$，并在使用梯形离散化时进一步降低到渐近最优成本$\mathical｛O}（\varEpilon ^{-2｝）$。我们提供了数值实验，强调了在这种粗略的前向方差设置下，多级方法在波动率指数期权定价中的效率。

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Multilevel Monte Carlo simulation for VIX options in the rough Bergomi model

We consider the pricing of VIX options in the rough Bergomi model. In this setting, the VIX random variable is defined by the one-dimensional integral of the exponential of a Gaussian process with correlated increments, hence approximate samples of the VIX can be constructed via discretization of the integral and simulation of a correlated Gaussian vector. A Monte-Carlo estimator of VIX options based on a rectangle discretization scheme and exact Gaussian sampling via the Cholesky method has a computational complexity of order $\mathcal{O}(\varepsilon^{-4})$ when the mean-squared error is set to $\varepsilon^2$. We demonstrate that this cost can be reduced to $\mathcal{O}(\varepsilon^{-2} \log^2(\varepsilon))$ combining the scheme above with the multilevel method, and further reduced to the asymptotically optimal cost $\mathcal{O}(\varepsilon^{-2})$ when using a trapezoidal discretization. We provide numerical experiments highlighting the efficiency of the multilevel approach in the pricing of VIX options in such a rough forward variance setting.

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来源期刊

Journal of Computational Finance BUSINESS, FINANCE-

CiteScore

0.90

自引率

0.00%

发文量

期刊介绍： The Journal of Computational Finance is an international peer-reviewed journal dedicated to advancing knowledge in the area of financial mathematics. The journal is focused on the measurement, management and analysis of financial risk, and provides detailed insight into numerical and computational techniques in the pricing, hedging and risk management of financial instruments. The journal welcomes papers dealing with innovative computational techniques in the following areas: Numerical solutions of pricing equations: finite differences, finite elements, and spectral techniques in one and multiple dimensions. Simulation approaches in pricing and risk management: advances in Monte Carlo and quasi-Monte Carlo methodologies; new strategies for market factors simulation. Optimization techniques in hedging and risk management. Fundamental numerical analysis relevant to finance: effect of boundary treatments on accuracy; new discretization of time-series analysis. Developments in free-boundary problems in finance: alternative ways and numerical implications in American option pricing.