Sparse non-negative super-resolution -- simplified and stabilised
Abstract
The convolution of a discrete measure, , with a local window function, , is a common model for a measurement device whose resolution is substantially lower than that of the objects being observed. Super-resolution concerns localising the point sources with an accuracy beyond the essential support of , typically from samples , where indicates an inexactness in the sample value. We consider the setting of being non-negative and seek to characterise all non-negative measures approximately consistent with the samples. We first show that is the unique non-negative measure consistent with the samples provided the samples are exact, i.e. , samples are available, and generates a Chebyshev system. This is independent of how close the sample locations are and {\em does not rely on any regulariser beyond non-negativity}; as such, it extends and clarifies the work by Schiebinger et al. and De Castro et al., who achieve the same results but require a total variation regulariser, which we show is unnecessary. Moreover, we characterise non-negative solutions consistent with the samples within the bound . Any such non-negative measure is within of the discrete measure generating the samples in the generalised Wasserstein distance, converging to one another as approaches zero. We also show how to make these general results, for windows that form a Chebyshev system, precise for the case of being a Gaussian window. The main innovation of these results is that non-negativity alone is sufficient to localise point sources beyond the essential sensor resolution.
Cite
@article{arxiv.1804.01490,
title = {Sparse non-negative super-resolution -- simplified and stabilised},
author = {Armin Eftekhari and Jared Tanner and Andrew Thompson and Bogdan Toader and Hemant Tyagi},
journal= {arXiv preprint arXiv:1804.01490},
year = {2019}
}
Comments
59 pages, 7 figures