Litcius/Paper detail

Entropic gradient descent algorithms and wide flat minima

Fabrizio Pittorino, Carlo Lucibello, Christoph Feinauer, Gabriele Perugini, Carlo Baldassi, Elizaveta Demyanenko, Riccardo Zecchina

2021Virtual Community of Pathological Anatomy (University of Castilla La Mancha)24 citationsDOI

Abstract

The properties of flat minima in the empirical risk landscape of neural networks have been debated for some time. Increasing evidence suggests they possess better generalization capabilities with respect to sharp ones. In this work we first discuss the relationship between alternative measures of flatness: the local entropy, which is useful for analysis and algorithm development, and the local energy, which is easier to compute and was shown empirically in extensive tests on state-of-the-art networks to be the best predictor of generalization capabilities. We show semi-analytically in simple controlled scenarios that these two measures correlate strongly with each other and with generalization. Then, we extend the analysis to the deep learning scenario by extensive numerical validations. We study two algorithms, entropy-stochastic gradient descent and replicated-stochastic gradient descent, that explicitly include the local entropy in the optimization objective. We devise a training schedule by which we consistently find flatter minima (using both flatness measures), and improve the generalization error for common architectures (e.g. ResNet, EfficientNet).

Topics & Concepts

Maxima and minimaStochastic gradient descentGeneralizationGradient descentComputer scienceAlgorithmEntropy (arrow of time)Flatness (cosmology)Artificial neural networkScheduleMathematical optimizationMathematicsArtificial intelligenceOperating systemPhysicsQuantum mechanicsMathematical analysisCosmologyStochastic Gradient Optimization TechniquesAdvanced Neural Network ApplicationsDomain Adaptation and Few-Shot Learning