Concetti Chiave
The authors propose an adaptive heavy ball method to efficiently solve ill-posed inverse problems, both linear and nonlinear, by incorporating a strongly convex regularization function to detect the desired solution features. The method adaptively chooses the step-sizes and momentum coefficients to achieve acceleration over the standard Landweber-type method.
Sintesi
The content discusses an ill-posed inverse problem of the form F(x) = y, where F could be a linear or nonlinear operator between Hilbert spaces X and Y. The authors consider the situation where the solution does not depend continuously on the data, which often occurs in practical applications due to noisy measurements.
The authors propose an adaptive heavy ball method (Algorithm 1) to solve this ill-posed inverse problem. The key aspects are:
- Incorporating a strongly convex regularization function R to determine a solution with desired features (e.g., non-negativity, sparsity, piecewise constancy).
- Adapting the step-sizes αδn and momentum coefficients βδn at each iteration to accelerate the convergence compared to the standard Landweber-type method.
- Deriving the update formulas for αδn and βδn based on minimizing an upper bound of the Bregman distance between the current iterate and the true solution.
- Proving that the proposed method is well-defined and the iteration terminates in finite steps using the discrepancy principle.
- Establishing the weak and strong convergence of the method under suitable assumptions.
The authors also present Algorithm 2, which is the counterpart of Algorithm 1 using the exact data y, to facilitate the convergence analysis.
Extensive numerical results demonstrate the superior performance of the proposed adaptive heavy ball method over the Landweber-type method in terms of reducing the required number of iterations and computational time.
Statistiche
∥yδ - y∥ ≤ δ
∥L(x)∥ ≤ L for all x ∈ B2ρ(x0)
∥F(x) - F(x̄) - L(x̄)(x - x̄)∥ ≤ η∥F(x) - F(x̄)∥ for all x, x̄ ∈ B2ρ(x0)
Citazioni
"In practical scenarios, data are acquired through experiments and thus the exact data may not be available; instead we only have measurement data corrupted by noise. Due to the ill-posed nature of the underlying problem, it is therefore important to develop algorithms to produce stable approximate solutions of (1) using noisy data."
"Extensive numerical simulations have demonstrated that the Landweber-type method (2) is a slowly convergent approach, often necessitating a large number of iteration steps before termination by the discrepancy principle. It is therefore important to develop strategies for accelerating the Landweber-type method (2) while maintaining its simple implementation feature."