1. An ADMM-Newton-CNN numerical approach to a TV model for identifying discontinuous diffusion coefficients in elliptic equations: convex case with gradient observations
- Author
-
Hangrui Yue, Wenyi Tian, and Xiaoming Yuan
- Subjects
Discretization ,Applied Mathematics ,35R30 49M41 90C25 ,Numerical Analysis (math.NA) ,Inverse problem ,Regularization (mathematics) ,Convexity ,Computer Science Applications ,Theoretical Computer Science ,Elliptic curve ,Nonlinear system ,symbols.namesake ,Signal Processing ,FOS: Mathematics ,Schur complement ,symbols ,Applied mathematics ,Mathematics - Numerical Analysis ,Newton's method ,Mathematical Physics ,Mathematics - Abstract
Identifying the discontinuous diffusion coefficient in an elliptic equation with observation data of the gradient of the solution is an important nonlinear and ill-posed inverse problem. Models with total variational (TV) regularization have been widely studied for this problem, while the theoretically required nonsmoothness property of the TV regularization and the hidden convexity of the models are usually sacrificed when numerical schemes are considered in the literature. In this paper, we show that the favorable nonsmoothness and convexity properties can be entirely kept if the well-known alternating direction method of multipliers (ADMM) is applied to the TV-regularized models, hence it is meaningful to consider designing numerical schemes based on the ADMM. Moreover, we show that one of the ADMM subproblems can be well solved by the active-set Newton method along with the Schur complement reduction method, and the other one can be efficiently solved by the deep convolutional neural network (CNN). The resulting ADMM-Newton-CNN approach is demonstrated to be easily implementable and very efficient even for higher-dimensional spaces with fine mesh discretization.
- Published
- 2021