English

Fractional Gaussian fields: a survey

Probability 2016-02-08 v2

Abstract

We discuss a family of random fields indexed by a parameter sRs\in \mathbb{R} which we call the fractional Gaussian fields, given by FGFs(Rd)=(Δ)s/2W, \mathrm{FGF}_s(\mathbb{R}^d)=(-\Delta)^{-s/2} W, where WW is a white noise on Rd\mathbb{R}^d and (Δ)s/2(-\Delta)^{-s/2} is the fractional Laplacian. These fields can also be parameterized by their Hurst parameter H=sd/2H = s-d/2. In one dimension, examples of FGFs\mathrm{FGF}_s processes include Brownian motion (s=1s = 1) and fractional Brownian motion (1/2<s<3/21/2 < s < 3/2). Examples in arbitrary dimension include white noise (s=0s = 0), the Gaussian free field (s=1s = 1), the bi-Laplacian Gaussian field (s=2s = 2), the log-correlated Gaussian field (s=d/2s = d/2), L\'evy's Brownian motion (s=d/2+1/2s = d/2 + 1/2), and multidimensional fractional Brownian motion (d/2<s<d/2+1d/2 < s < d/2 + 1). These fields have applications to statistical physics, early-universe cosmology, finance, quantum field theory, image processing, and other disciplines. We present an overview of fractional Gaussian fields including covariance formulas, Gibbs properties, spherical coordinate decompositions, restrictions to linear subspaces, local set theorems, and other basic results. We also define a discrete fractional Gaussian field and explain how the FGFs\mathrm{FGF}_s with s(0,1)s \in (0,1) can be understood as a long range Gaussian free field in which the potential theory of Brownian motion is replaced by that of an isotropic 2s2s-stable L\'evy process.

Keywords

Cite

@article{arxiv.1407.5598,
  title  = {Fractional Gaussian fields: a survey},
  author = {Asad Lodhia and Scott Sheffield and Xin Sun and Samuel S. Watson},
  journal= {arXiv preprint arXiv:1407.5598},
  year   = {2016}
}

Comments

73 pages

R2 v1 2026-06-22T05:09:06.564Z