On the Heston Model with Stochastic Volatility: Analytic Solutions and Complete Markets

Abstract

We study the Heston model for pricing European options on stocks with stochastic volatility. This is a Black\--Scholes\--type equation whose spatial domain for the logarithmic stock price x∈ and the variance v∈ (0,∞) is the half\--plane = × (0,∞). The volatility\/ is then given by v. The diffusion equation for the price of the European call option p = p(x,v,t) at time t≤ T is parabolic and degenerates at the boundary ∂ = × \0\ as v 0+. The goal is to hedge with this option against volatility fluctuations, i.e., the function v p(x,v,t) (0,∞) and its (local) inverse are of particular interest. We prove that ∂ p∂ v(x,v,t) = 0 holds almost everywhere in × (-∞,T) by establishing the analyticity of p in both, space (x,v) and time t variables. To this end, we are able to show that the Black\--Scholes\--type operator, which appears in the diffusion equation, generates a holomorphic C0-semigroup in a suitable weighted L2-space over . We show that the C0-semigroup solution can be extended to a holomorphic function in a complex domain in 2× , by establishing some new a~priori weighted L2-estimates over certain complex "shifts" of for the unique holomorphic extension. These estimates depend only on the weighted L2-norm of the terminal data over (at t=T).