Adaptive minimax estimation for discretely observed L\'evy processes

TL;DR

This paper develops a spectral estimator for the density of increments of Lévy processes, achieving minimax optimal rates under broad conditions, with a focus on both low- and high-frequency sampling regimes.

Contribution

It introduces a new adaptive spectral estimator for Lévy process increments, providing non-asymptotic, minimax optimal bounds under weaker assumptions than prior work.

Findings

Estimator is minimax optimal in various regimes.

Convergence rates depend on jump activity and process components.

Proposed data-driven estimator is simple and computationally efficient.

Abstract

In this paper, we study the nonparametric estimation of the density $f_\Delta$ of an increment of a L\'evy process $X$ based on $n$ observations with a sampling rate $\Delta$. The class of L\'evy processes considered is broad, including both processes with a Gaussian component and pure jump processes. A key focus is on processes where $f_\Delta$ is smooth for all $\Delta$. We introduce a spectral estimator of $f_\Delta$ and derive both upper and lower bounds, showing that the estimator is minimax optimal in both low- and high-frequency regimes. Our results differ from existing work by offering weaker, easily verifiable assumptions and providing non-asymptotic results that explicitly depend on $\Delta$. In low-frequency settings, we recover parametric convergence rates, while in high-frequency settings, we identify two regimes based on whether the Gaussian or jump components dominate. The rates of convergence are closely tied to the jump activity, with continuity between the Gaussian case and more general jump processes. Additionally, we propose a fully data-driven estimator with proven simplicity and rapid implementation, supported by numerical experiments.