MEMS Seminar: Fractional Operators with Inhomogeneous Boundary Conditions - Analysis, Control and Discretization
Wednesday, October 11, 2017
12:00 pm - 1:00 pm
Fitzpatrick Center Schiciano Auditorium Side A
Professor Harbir Antil
In this talk we introduce new characterizations of spectral fractional Laplacian to incorporate nonhomogeneous Dirichlet and Neumann boundary conditions. The classical cases with homogeneous boundary conditions arise as a special case. We apply our definition to fractional elliptic equations of order $s \in (0,1)$ with nonzero Dirichlet and Neumann boundary conditions. Here the domain $\Omega$ is assumed to be a bounded, quasi-convex Lipschitz domain.
To impose the nonzero boundary conditions, we construct fractional harmonic extensions of the boundary data. It is shown that solving for the fractional harmonic extension is equivalent to solving for the standard harmonic extension in the very-weak form. The latter result is of independent interest as well. The remaining fractional elliptic problem (with homogeneous boundary data) can be realized using the existing techniques. We introduce finite element discretizations and derive discretization error estimates in natural norms, which are confirmed by numerical experiments. We also apply our characterizations to Dirichlet and Neumann boundary optimal control problems with fractional elliptic equation as constraints.
H. Antil got his PhD. in 2009 at University of Houston. After spending a year at Rice University, he continued his work at University of Maryland. He joined George Mason University in 2012 as an assistant professor. His research interests include: PDE Constrained Optimization (optimal control, shape optimization), free boundary problems, nonlocal PDEs, and model order reduction.
Lunch will be served at 11:30 am.