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 fast and provable admm


Fast and Provable ADMM for Learning with Generative Priors

Neural Information Processing Systems

In this work, we propose a (linearized) Alternating Direction Method-of-Multipliers (ADMM) algorithm for minimizing a convex function subject to a nonconvex constraint. We focus on the special case where such constraint arises from the specification that a variable should lie in the range of a neural network. This is motivated by recent successful applications of Generative Adversarial Networks (GANs) in tasks like compressive sensing, denoising and robustness against adversarial examples. The derived rates for our algorithm are characterized in terms of certain geometric properties of the generator network, which we show hold for feedforward architectures, under mild assumptions. Unlike gradient descent (GD), it can efficiently handle non-smooth objectives as well as exploit efficient partial minimization procedures, thus being faster in many practical scenarios.


Reviews: Fast and Provable ADMM for Learning with Generative Priors

Neural Information Processing Systems

I think the "global optimization" aspect of the main result and the fast (i.e., linear) convergence rate are very interesting, and perhaps also surprising. For example, for the least square problem min_z A G(z) - b prior works such as Hand & Voroninski [2017] and Heckel et al [2019] have established the global optimization aspect of simple gradient descent like algorithms. But the result obtained in this paper is much more general, and also applies to formulations with extra nonsmooth terms, with a practical numerical method. Moreover, general understanding of ADMM applied to nonconvex problems is still very rare. I think this result is definitely a beautiful addition to this line of literature also.


Fast and Provable ADMM for Learning with Generative Priors

Neural Information Processing Systems

In this work, we propose a (linearized) Alternating Direction Method-of-Multipliers (ADMM) algorithm for minimizing a convex function subject to a nonconvex constraint. We focus on the special case where such constraint arises from the specification that a variable should lie in the range of a neural network. This is motivated by recent successful applications of Generative Adversarial Networks (GANs) in tasks like compressive sensing, denoising and robustness against adversarial examples. The derived rates for our algorithm are characterized in terms of certain geometric properties of the generator network, which we show hold for feedforward architectures, under mild assumptions. Unlike gradient descent (GD), it can efficiently handle non-smooth objectives as well as exploit efficient partial minimization procedures, thus being faster in many practical scenarios.


Fast and Provable ADMM for Learning with Generative Priors

Neural Information Processing Systems

In this work, we propose a (linearized) Alternating Direction Method-of-Multipliers (ADMM) algorithm for minimizing a convex function subject to a nonconvex constraint. We focus on the special case where such constraint arises from the specification that a variable should lie in the range of a neural network. This is motivated by recent successful applications of Generative Adversarial Networks (GANs) in tasks like compressive sensing, denoising and robustness against adversarial examples. The derived rates for our algorithm are characterized in terms of certain geometric properties of the generator network, which we show hold for feedforward architectures, under mild assumptions. Unlike gradient descent (GD), it can efficiently handle non-smooth objectives as well as exploit efficient partial minimization procedures, thus being faster in many practical scenarios.