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Rapid, Robust, and Reliable Blind Deconvolution via Nonconvex Optimization
We study the question of reconstructing two signals and from their
convolution . This problem, known as {\em blind deconvolution},
pervades many areas of science and technology, including astronomy, medical
imaging, optics, and wireless communications. A key challenge of this intricate
non-convex optimization problem is that it might exhibit many local minima. We
present an efficient numerical algorithm that is guaranteed to recover the
exact solution, when the number of measurements is (up to log-factors) slightly
larger than the information-theoretical minimum, and under reasonable
conditions on and . The proposed regularized gradient descent algorithm
converges at a geometric rate and is provably robust in the presence of noise.
To the best of our knowledge, our algorithm is the first blind deconvolution
algorithm that is numerically efficient, robust against noise, and comes with
rigorous recovery guarantees under certain subspace conditions. Moreover,
numerical experiments do not only provide empirical verification of our theory,
but they also demonstrate that our method yields excellent performance even in
situations beyond our theoretical framework
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