English

The martingale problem for geometric stable-like processes

Probability 2024-12-30 v1

Abstract

We prove that the martingale problem is well posed for pure-jump L\'evy-type operators of the form (Lf)(x)=Rd{0}(f(x+h)f(x)(f(x)h)1h<1)K(x,h)dh, (\mathcal Lf)(x) = \int_{\mathbb R^d \setminus \{0\}} \left(f(x+h)-f(x) - (\nabla f(x) \cdot h)1_{\|h\| < 1}\right)K(x,h) dh, where K(x,)K(x,\cdot) is a jump kernel of the form K(x,h)l(h)hdK(x,h) \sim \frac{l(\|h\|)}{\|h\|^d} for each xRd,h<1x \in \mathbb R^d,\|h\|<1, and ll is a positive function that is slowly varying at 00, under suitable assumptions on KK. This includes jump kernels such as those of α\alpha-geometric stable processes, α(0,2]\alpha \in (0,2].

Keywords

Cite

@article{arxiv.2412.18677,
  title  = {The martingale problem for geometric stable-like processes},
  author = {Sarvesh Ravichandran Iyer},
  journal= {arXiv preprint arXiv:2412.18677},
  year   = {2024}
}

Comments

29 pages, to be submitted to Stochastic Processes and Applications

R2 v1 2026-06-28T20:48:25.627Z