# Sampled Tikhonov Regularization for Large Linear Inverse Problems

**Authors:** J. Tanner Slagel, Julianne Chung, Matthias Chung, David Kozak, Luis, Tenorio

arXiv: 1812.06165 · 2018-12-18

## TL;DR

This paper introduces sampling-based iterative methods for large-scale inverse problems, enabling Tikhonov regularization with adaptive parameter updates and demonstrating effectiveness in super-resolution imaging.

## Contribution

It proposes a family of sampled iterative methods that incorporate data as it becomes available, with adaptive regularization parameter updates for improved convergence.

## Key findings

- Methods converge to Tikhonov-regularized solutions
- Adaptive regularization improves solution quality
- Numerical examples demonstrate practical effectiveness

## Abstract

In this paper, we investigate iterative methods that are based on sampling of the data for computing Tikhonov-regularized solutions. We focus on very large inverse problems where access to the entire data set is not possible all at once (e.g., for problems with streaming or massive datasets). Row-access methods provide an ideal framework for solving such problems, since they only require access to "blocks" of the data at any given time. However, when using these iterative sampling methods to solve inverse problems, the main challenges include a proper choice of the regularization parameter, appropriate sampling strategies, and a convergence analysis. To address these challenges, we first describe a family of sampled iterative methods that can incorporate data as they become available (e.g., randomly sampled). We consider two sampled iterative methods, where the iterates can be characterized as solutions to a sequence of approximate Tikhonov problems. The first method requires the regularization parameter to be fixed a priori and converges asymptotically to an unregularized solution for randomly sampled data. This is undesirable for inverse problems. Thus, we focus on the second method where the main benefits are that the regularization parameter can be updated during the iterative process and the iterates converge asymptotically to a Tikhonov-regularized solution. We describe adaptive approaches to update the regularization parameter that are based on sampled residuals, and we describe a limited-memory variant for larger problems. Numerical examples, including a large-scale super-resolution imaging example, demonstrate the potential for these methods.

## Full text

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## Figures

7 figures with captions in the complete paper: https://tomesphere.com/paper/1812.06165/full.md

## References

44 references — full list in the complete paper: https://tomesphere.com/paper/1812.06165/full.md

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Source: https://tomesphere.com/paper/1812.06165