English

Asymptotics for the Euler-Discretized Hull-White Stochastic Volatility Model

Mathematical Finance 2018-02-13 v1 Numerical Analysis Probability

Abstract

We consider the stochastic volatility model dSt=σtStdWt,dσt=ωσtdZtdS_t = \sigma_t S_t dW_t,d\sigma_t = \omega \sigma_t dZ_t, with (Wt,Zt)(W_t,Z_t) uncorrelated standard Brownian motions. This is a special case of the Hull-White and the β=1\beta=1 (log-normal) SABR model, which are widely used in financial practice. We study the properties of this model, discretized in time under several applications of the Euler-Maruyama scheme, and point out that the resulting model has certain properties which are different from those of the continuous time model. We study the asymptotics of the time-discretized model in the nn\to \infty limit of a very large number of time steps of size τ\tau, at fixed β=12ω2τn2\beta=\frac12\omega^2\tau n^2 and ρ=σ02τ\rho=\sigma_0^2\tau, and derive three results: i) almost sure limits, ii) fluctuation results, and iii) explicit expressions for growth rates (Lyapunov exponents) of the positive integer moments of StS_t. Under the Euler-Maruyama discretization for (St,logσt)(S_t,\log \sigma_t), the Lyapunov exponents have a phase transition, which appears in numerical simulations of the model as a numerical explosion of the asset price moments. We derive criteria for the appearance of these explosions.

Keywords

Cite

@article{arxiv.1707.00899,
  title  = {Asymptotics for the Euler-Discretized Hull-White Stochastic Volatility Model},
  author = {Dan Pirjol and Lingjiong Zhu},
  journal= {arXiv preprint arXiv:1707.00899},
  year   = {2018}
}

Comments

42 pages, 7 figures

R2 v1 2026-06-22T20:37:20.892Z