Recovering of dielectric constants of explosives via a globally strictly convex cost functional
arXiv:1408.0583
Abstract
The inverse problem of estimating dielectric constants of explosives using boundary measurements of one component of the scattered electric field is addressed. It is formulated as a coefficient inverse problem for a hyperbolic differential equation. After applying the Laplace transform, a new cost functional is constructed and a variational problem is formulated. The key feature of this functional is the presence of the Carleman Weight Function for the Laplacian. The strict convexity of this functional on a bounded set in a Hilbert space of an arbitrary size is proven. This allows for establishing the global convergence of the gradient descent method. Some results of numerical experiments are presented.
Keywords: Coefficient inverse problem, Laplace transform, Carleman weight function, strictly convex cost functional, global convergence, Laguerre functions, numerical experiments