English

Jump filtering and efficient drift estimation for L\'evy-driven SDE's

Statistics Theory 2016-03-18 v1 Statistics Theory

Abstract

The problem of drift estimation for the solution XX of a stochastic differential equation with L\'evy-type jumps is considered under discrete high-frequency observations with a growing observation window. An efficient and asymptotically normal estimator for the drift parameter is constructed under minimal conditions on the jump behavior and the sampling scheme. In the case of a bounded jump measure density these conditions reduce to nΔn3ϵ0,n \Delta_n^{3-\epsilon}\to 0, where nn is the number of observations and Δn\Delta_n is the maximal sampling step. This result relaxes the condition nΔn20n\Delta_n^2 \to 0 usually required for joint estimation of drift and diffusion coefficient for SDE's with jumps. The main challenge in this estimation problem stems from the appearance of the unobserved continuous part XcX^c in the likelihood function. In order to construct the drift estimator we recover this continuous part from discrete observations. More precisely, we estimate, in a nonparametric way, stochastic integrals with respect to XcX^c. Convergence results of independent interest are proved for these nonparametric estimators. Finally, we illustrate the behavior of our drift estimator for a number of popular L\'evy-driven models from finance.

Keywords

Cite

@article{arxiv.1603.05290,
  title  = {Jump filtering and efficient drift estimation for L\'evy-driven SDE's},
  author = {Arnaud Gloter and Dasha Loukianova and Hilmar Mai},
  journal= {arXiv preprint arXiv:1603.05290},
  year   = {2016}
}

Comments

40 pages

R2 v1 2026-06-22T13:12:43.492Z