A Nonlocal Denoising Algorithm for Manifold-Valued Images Using Second Order Statistics
This work addresses denoising for specialized data types like symmetric positive definite matrices, which are common in real-world applications, representing an incremental extension of existing methods to a new domain.
The paper tackles the problem of denoising manifold-valued images, such as those with phase or directional entries, by generalizing a state-of-the-art nonlocal patch-based Bayesian method to handle data on manifolds, resulting in a new algorithm demonstrated through proof-of-concept examples.
Nonlocal patch-based methods, in particular the Bayes' approach of Lebrun, Buades and Morel (2013), are considered as state-of-the-art methods for denoising (color) images corrupted by white Gaussian noise of moderate variance. This paper is the first attempt to generalize this technique to manifold-valued images. Such images, for example images with phase or directional entries or with values in the manifold of symmetric positive definite matrices, are frequently encountered in real-world applications. Generalizing the normal law to manifolds is not canonical and different attempts have been considered. Here we focus on a straightforward intrinsic model and discuss the relation to other approaches for specific manifolds. We reinterpret the Bayesian approach of Lebrun et al. (2013) in terms of minimum mean squared error estimation, which motivates our definition of a corresponding estimator on the manifold. With this estimator at hand we present a nonlocal patch-based method for the restoration of manifold-valued images. Various proof of concept examples demonstrate the potential of the proposed algorithm.