Canonical Rough Path over Tempered Fractional Brownian Motion: Existence, Construction, and Applications
Abstract: We construct a canonical geometric rough path over $d$-dimensional tempered fractional Brownian motion (tfBm) for any Hurst parameter $H > 1/4$ and tempering parameter $λ> 0$. The main challenge stems from the non-homogeneous nature of the tfBm covariance, which exhibits a power-law structure at small scales and exponential decay at large scales. Our primary contribution is a detailed analysis of this covariance, proving it has finite 2D $ρ$-variation for $ρ= 1/(2H)$. This verifies the criterion of Friz and Victoir, guaranteeing the existence of a rough path lift. We then provide an explicit construction of the rough path $\mathbf{B}{H,λ} = (B{H,λ}, \mathbb{B}_{H,λ})$ via $L2$-limits, establishing its basic properties with explicit constants $C(H,λ,T)$. As direct consequences, we obtain: (i) a complete characterization of integration regimes, with Young integration applicable for $H > 1/2$ and rough path theory necessary and sufficient for $H \in (1/4, 1/2]$; (ii) the well-posedness of rough differential equations driven by tfBm; and (iii) the foundation for signature calculus for tfBm, including the existence and factorial decay of the signature. Numerical experiments confirm the theoretical convergence rates $\mathcal{O}(N{-2H})$ for the Lévy area approximation and $\mathcal{O}(n{-H})$ for the associated Milstein scheme. This work provides the first comprehensive pathwise framework for stochastic calculus with tfBm.
Paper Prompts
Sign up for free to create and run prompts on this paper using GPT-5.
Top Community Prompts
Collections
Sign up for free to add this paper to one or more collections.