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Information-Theoretic Lower Bounds for Compressive Sensing With Generative Models

Zhaoqiang Liu, Jonathan Scarlett

2020IEEE Journal on Selected Areas in Information Theory27 citationsDOIOpen Access PDF

Abstract

It has recently been shown that for compressive sensing, significantly fewer measurements may be required if the sparsity assumption is replaced by the assumption the unknown vector lies near the range of a suitably-chosen generative model. In particular, in (Bora et al., 2017) it was shown roughly O(k log L) random Gaussian measurements suffice for accurate recovery when the generative model is an L-Lipschitz function with bounded k-dimensional inputs, and O(kdlogw) measurements suffice when the generative model is a k-input ReLU network with depth d and width w. In this paper, we establish corresponding algorithm-independent lower bounds on the sample complexity using tools from minimax statistical analysis. In accordance with the above upper bounds, our results are summarized as follows: (i) We construct an L-Lipschitz generative model capable of generating group-sparse signals, and show that the resulting necessary number of measurements is Ω(k logL); (ii) Using similar ideas, we construct ReLU networks with high depth and/or high depth for which the necessary number of measurements scales as Ω(kd logw/logn) (with output dimension n), and in some cases Ω(kd logw). As a result, we establish that the scaling laws derived in (Bora et al., 2017) are optimal or near-optimal in the absence of further assumptions.

Topics & Concepts

MinimaxMathematicsLipschitz continuityGenerative modelDimension (graph theory)Bounded functionUpper and lower boundsGenerative grammarRange (aeronautics)GaussianCompressed sensingFunction (biology)CombinatoricsAlgorithmDiscrete mathematicsMathematical optimizationComputer sciencePure mathematicsMathematical analysisArtificial intelligenceBiologyPhysicsMaterials scienceEvolutionary biologyQuantum mechanicsComposite materialSparse and Compressive Sensing TechniquesMicrowave Imaging and Scattering AnalysisDistributed Sensor Networks and Detection Algorithms