Low Frequency L\'evy Copula Estimation
Abstract
Let be a -dimensional L\'evy process with L\'evy triplet and . Given the low frequency observations , the dependence structure of the jumps of is estimated. The L\'evy measure describes the average jump behavior in a time unit. Thus, the aim is to estimate the dependence structure of by estimating the L\'evy copula of , cf. Kallsen and Tankov \cite{KalTan}. We use the low frequency techniques presented in a one dimensional setting in Neumann and Rei{\ss} \cite{NeuRei} and Nickl and Rei{\ss} \cite{NicRei} to construct a L\'evy copula estimator based on the above observations. In doing so we prove uniformly on compact sets bounded away from zero with the convergence rate . This convergence holds under quite general assumptions, which also include L\'evy triplets with and of arbitrary Blumenthal-Getoor index . Note that in a low frequency observation scheme, it is statistically difficult to distinguish between infinitely many small jumps and a Brownian motion part. Hence, the rather slow convergence rate is not surprising. In the complementary case of a compound Poisson process (CPP), an estimator for the copula of the jump distribution of the CPP is constructed under the same observation scheme. This copula is the analogue to the L\'evy copula in the finite jump activity case, i.e. the CPP case. Here we establish with the convergence rate uniformly on compact sets bounded away from zero. Both convergence rates are optimal in the sense of Neumann and Rei{\ss}.
Cite
@article{arxiv.1409.8627,
title = {Low Frequency L\'evy Copula Estimation},
author = {Christian Palmes},
journal= {arXiv preprint arXiv:1409.8627},
year = {2014}
}