Approximation of stochastic integrals with jumps via weighted BMO approach

TL;DR

This paper develops a new weighted BMO-based method for approximating stochastic integrals with jumps, providing error estimates, optimization strategies, and applications to financial hedging with Levy processes.

Contribution

It introduces a novel approximation scheme for jump-driven stochastic integrals using weighted BMO techniques, extending error analysis and optimization to broader jump activity regimes.

Findings

Achieves $L_p$-error estimates depending on weights.

Extends approximation to $ ext{alpha}$-stable jumps with $ ext{alpha} ext{in}(0,2)$.

Applies to mean-variance hedging with exponential Levy processes.

Abstract

This article investigates discrete-time approximations of stochastic integrals driven by semimartingales with jumps via weighted bounded mean oscillation (BMO) approach. This approach enables $L_p$-estimates, $p \in (2, \infty)$, for the approximation error depending on the weight, and it allows a change of the underlying measure which leaves the error estimates unchanged. To take advantage of this approach, we propose a new approximation scheme obtained from a correction for the Riemann approximation based on tracking jumps of the underlying semimartingale. We also discuss a way to optimize the approximation rate by adapting the discretization times to the setting. When the small jump activity of the semimartingale behaves like an $\alpha$-stable process with $\alpha \in (1, 2)$, our scheme achieves under a regular regime the same convergence rate for the error as in Rosenbaum and Tankov [\textit{Ann. Appl. Probab.} \textbf{24} (2014) 1002--1048]. Moreover, our approach extends to the case $\alpha \in (0, 1]$ and to the $L_p$-setting which are not treated there. As an application, we apply the methods in the special case where the semimartingale is an exponential L\'evy process to mean-variance hedging of European type options.