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Stochastic gradient descent for linear inverse problems in Hilbert spaces

Shuai Lu, Peter Mathé

2021Mathematics of Computation16 citationsDOIOpen Access PDF

Abstract

We investigate stochastic gradient decent (SGD) for solving full infinite dimensional ill-posed problems in Hilbert spaces. We allow for batch-size versions of SGD where the randomly chosen batches incur noise fluctuations. Based on the corresponding bias-variance decomposition we provide bounds for the root mean squared error. These bounds take into account the discretization levels, the decay of the step-size, which is more flexible than in existing results, and the underlying smoothness in terms of general source conditions. This allows to apply SGD to severely ill-posed problems. The obtained error bounds exhibit three stages of the performance of SGD. In particular, the pre-asymptotic behavior can be well seen. Some numerical studies verify the theoretical predictions.

Topics & Concepts

MathematicsSmoothnessDiscretizationStochastic gradient descentHilbert spaceApplied mathematicsHilbert curveInverseInverse problemMathematical optimizationMathematical analysisAlgorithmComputer scienceGeometryMachine learningArtificial neural networkNumerical methods in inverse problemsSparse and Compressive Sensing TechniquesStatistical Methods and Inference
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