English

General Least Gradient Problems with Obstacle

Analysis of PDEs 2019-04-17 v1

Abstract

We study existence, structure, uniqueness and regularity of solutions of the obstacle problem \begin{equation*} \inf_{u\in BV_f(\Omega)}\int_{\mathbb{R}^n}\phi(x,Du), \end{equation*} where BVf(Ω)={uBV(Ω):uψ in Ω and uΩ=fΩ}BV_f(\Omega)=\{u\in BV(\Omega): u\geq \psi \text{ in }\Omega\text{ and } u|_{\partial \Omega}=f|_{\partial \Omega}\}, fW01,1(Rn)f \in W^{1,1}_0(\mathbb{R}^n), ψ\psi is the obstacle, and ϕ(x,ξ)\phi(x,\xi) is a convex, continuous and homogeneous function of degree one with respect to the ξ\xi variable. We show that every minimizer of this problem is also a minimizer of the least gradient problem infuAf(Ω)Rnϕ(x,Du),\inf_{u\in \mathcal{A}_f(\Omega)}\int_{\mathbb{R}^n}\phi(x,Du), where Af(Ω)={uBV(Ω):uψ, and u=f in Ωc}\mathcal{A}_f(\Omega)=\{u\in BV(\Omega): u\geq \psi, \text{ and } u=f \text{ in }\Omega^c\}. Moreover, there exists a vector field TT with T0\nabla \cdot T \leq 0 in Ω\Omega which determines the structure of all minimizers of these two problems, and TT is divergence free on {xΩ:u(x)>ψ(x)}\{x\in \Omega: u(x)>\psi(x)\} for any minimizer uu. We also present uniqueness and regularity results that are based on maximum principles for minimal surfaces. Since minimizers of the least gradient problems with obstacle do not hit small enough obstacles, the results presented in this paper extend several results in the literature about least gradient problems without obstacle.

Keywords

Cite

@article{arxiv.1904.07487,
  title  = {General Least Gradient Problems with Obstacle},
  author = {Morteza Fotouhi and Amir Moradifam},
  journal= {arXiv preprint arXiv:1904.07487},
  year   = {2019}
}
R2 v1 2026-06-23T08:40:54.006Z