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Proof of the Theory-to-Practice Gap in Deep Learning via Sampling Complexity bounds for Neural Network Approximation Spaces

Philipp Grohs, Felix Voigtlaender

2023Foundations of Computational Mathematics36 citationsDOIOpen Access PDF

Abstract

Abstract We study the computational complexity of (deterministic or randomized) algorithms based on point samples for approximating or integrating functions that can be well approximated by neural networks. Such algorithms (most prominently stochastic gradient descent and its variants) are used extensively in the field of deep learning. One of the most important problems in this field concerns the question of whether it is possible to realize theoretically provable neural network approximation rates by such algorithms. We answer this question in the negative by proving hardness results for the problems of approximation and integration on a novel class of neural network approximation spaces. In particular, our results confirm a conjectured and empirically observed theory-to-practice gap in deep learning. We complement our hardness results by showing that error bounds of a comparable order of convergence are (at least theoretically) achievable.

Topics & Concepts

Complement (music)Artificial neural networkMathematicsApproximation errorStochastic gradient descentApproximation algorithmDeep learningConvergence (economics)Field (mathematics)Stochastic approximationClass (philosophy)AlgorithmArtificial intelligenceComputer scienceApplied mathematicsMathematical optimizationKey (lock)Pure mathematicsPhenotypeComplementationBiochemistryEconomicsGeneEconomic growthComputer securityChemistryStochastic Gradient Optimization TechniquesMachine Learning and AlgorithmsDomain Adaptation and Few-Shot Learning
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