Parameter Estimation for Complex α-Fractional Brownian Bridge
Abstract
We study the statistical inference problem for a complex α-fractional Brownian bridge process Z defined by the stochastic differential equation \[ dZt = -α ZtT - t dt + dζt, t ∈ [0, T), \] with initial condition Z0 = 0, where α = λ - -1w, λ > 0, w ∈ R and ζt is a complex fractional Brownian motion. We establish the well-posedness of the fractional Brownian bridge Zt over the time interval [0, T] for all H ∈ (0, 1), and prove the strong consistency and the asymptotic distribution for the classic least squares estimator of the parameter \(α\) when \(H ∈ (12, 1)\). The proofs are based on stochastic analysis elements about complex multiple Wiener-It\o integrals and the complex Malliavin calculus. Unlike the real-valued fractional Brownian bridge considered in the literature, the two-dimensional limiting distribution has non-Cauchy marginal distributions.
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