Abstract
For the past few decades, various algorithms have been proposed to solve convex minimization problems in the form of the sum of two lower semicontinuous and convex functions. The convergence of these algorithms was guaranteed under the L-Lipschitz condition on the gradient of the objective function. In recent years, an inertial technique has been widely used to accelerate the convergence behavior of an algorithm. In this work, we introduce a new forward–backward splitting algorithm using a new line search and inertial technique to solve convex minimization problems in the form of the sum of two lower semicontinuous and convex functions. A weak convergence of our proposed method is established without assuming the L-Lipschitz continuity of the gradient of the objective function. Moreover, a complexity theorem is also given. As applications, we employed our algorithm to solve data classification and image restoration by conducting some experiments on these problems. The performance of our algorithm was evaluated using various evaluation tools. Furthermore, we compared its performance with other algorithms. Based on the experiments, we found that the proposed algorithm performed better than other algorithms mentioned in the literature.
Highlights
The convex minimization problem has been studied intensively for the past few decades due to its wide range of applications in various real-world problems
The problem of finding an unknown reaction term of such an equation can be formulated as a coefficient inverse problem (CIP) for a partial differential equation (PDE)
We introduce an accelerated algorithm by utilizing Line Search 3 as follows (Algorithm 9)
Summary
The convex minimization problem has been studied intensively for the past few decades due to its wide range of applications in various real-world problems. Numerical methods for solving CIPs for PDEs, as well as their applications to various subjects have been widely studied and analyzed; for more comprehensive information on this topic, see [1,2,3,4,5]. To obtain a globally convergent method for solving CIPs for PDEs, many authors have employed the convexification technique, which reformulates CIPs as convex minimization problems; for a more in-depth development and discussion, we refer to [6,7,8]. More examples of convex minimization problems are signal and image processing, compressed sensing, and machine learning tasks such as regression and classification; see [9,10,11,12,13,14,15,16] and the references therein for more information
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