Asymptotics for rough stochastic volatility models

Abstract

Using the large deviation principle (LDP) for a re-scaled fractional Brownian motion BHt where the rate function is defined via the reproducing kernel Hilbert space, we compute small-time asymptotics for a correlated fractional stochastic volatility model of the form dSt=Stσ(Yt) ( dWt + dBt), \,dYt=dBHt where σ is α-H\"older continuous for some α∈(0,1]; in particular, we show that tH-12 St satisfies the LDP as t0 and the model has a well-defined implied volatility smile as t 0, when the log-moneyness k(t)=x t12-H. Thus the smile steepens to infinity or flattens to zero depending on whether H∈(0,12) or H∈(12,1). We also compute large-time asymptotics for a fractional local-stochastic volatility model of the form: dSt= Stβ |Yt|p dWt,dYt=dBHt, and we generalize two identities in Matsumoto&Yor05 to show that 1t2H 1t∫0t e2 BHs ds and 1t2H( ∫0t e2(μ s+BHs) ds-2 μ t) converge in law to 2max0 s 1 BHs and 2B1 respectively for H ∈ (0,12) and μ>0 as t ∞.