Periodic homogenization of non-symmetric Lévy-type processes (2007.03388v1)

Abstract: In this paper, we study homogenization problem for strong Markov processes on $\R^d$ having infinitesimal generators $$ \sL f(x)=\int_{\R^d}\left(f(x+z)-f(x)-\langle \nabla f(x), z\rangle \I_{{|z|\le 1}} \right) k(x,z)\, \Pi (dz) +\langle b(x), \nabla f(x) \rangle, \quad f\in C^2_b (\R^d) $$ in periodic media, where $\Pi$ is a non-negative measure on $\R^d$ that does not charge the origin $0$, satisfies $\int_{\R^d} (1 \wedge |z|^2)\, \Pi (dz)<\infty$, and can be singular with respect to the Lebesgue measure on $\R^d$. Under a proper scaling, we show the scaled processes converge weakly to L\'evy processes on $\R^d$. The results are a counterpart of the celebrated work \cite{BLP,Bh} in the jump-diffusion setting. In particular, we completely characterize the homogenized limiting processes when $b(x) $ is a bounded continuous multivariate 1-periodic $\R^d$-valued function, $k(x,z)$ is a non-negative bounded continuous function that is multivariate 1-periodic in both $x$ and $z$ variables, and, in spherical coordinate $z=(r, \theta) \in \R_+\times \bS^{d-1}$, $$ \I_{{|z|>1}}\,\Pi (dz) = \I_{{ r>1}} \varrho_0(d\theta) \, \frac{ dr }{r^{1+\alpha}} $$ with $\alpha\in (0,\infty)$ and $\varrho_0$ being any finite measure on the unit sphere $\bS^{d-1}$ in $\R^d$. Different phenomena occur depending on the values of $\alpha$; there are five cases: $\alpha \in (0, 1)$, $\alpha =1$, $\alpha \in (1, 2)$, $\alpha =2$ and $\alpha \in (2, \infty)$.