The roughness exponent and its model-free estimation

Abstract

Motivated by pathwise stochastic calculus, we say that a continuous real-valued function x admits the roughness exponent R if the pth variation of x converges to zero if p>1/R and to infinity if p<1/R. For the sample paths of many stochastic processes, such as fractional Brownian motion, the roughness exponent exists and equals the standard Hurst parameter. In our main result, we provide a mild condition on the Faber--Schauder coefficients of x under which the roughness exponent exists and is given as the limit of the classical Gladyshev estimates Rn(x). This result can be viewed as a strong consistency result for the Gladyshev estimators in an entirely model-free setting, because it works strictly trajectory-wise and requires no probabilistic assumptions. Nonetheless, our proof is probabilistic and relies on a martingale that is hidden in the Faber--Schauder expansion of x. Since the Gladyshev estimators are not scale-invariant, we construct several scale-invariant estimators that are derived from the sequence ( Rn)n∈ N. We also discuss how a dynamic change in the roughness parameter of a time series can be detected. Finally, we extend our results to the case in which the pth variation of x is defined over a sequence of unequally spaced partitions. Our results are illustrated by means of high-frequency financial time series.