Iterative reverse filters have been recently developed to address the problem of removing effects of a black box image filter. Because numerous iterations are usually required to achieve the desired result, the processing speed is slow. In this paper, we propose to use fixed-point acceleration techniques to tackle this problem. We present an interpretation of existing reverse filters as fixed-point iterations and discuss their relationship with gradient descent. We then present extensive experimental results to demonstrate the performance of fixed-point acceleration techniques named after: Anderson, Chebyshev, Irons, and Wynn. We also compare the performance of these techniques with that of gradient descent acceleration. Key findings of this work include: (1) Anderson acceleration can make a non-convergent reverse filter convergent, (2) the T-method with an acceleration technique is highly efficient and effective, and (3) in terms of processing speed, all reverse filters can benefit from one of the acceleration techniques.
History
Publication Date
2023-10-01
Journal
Signal, Image and Video Processing
Volume
17
Pagination
9p. (p.3585–3593)
Publisher
Springer
ISSN
1863-1703
Rights Statement
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