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Nonconvex Sparse Regularization for Deep Neural Networks and Its Optimality

Ilsang Ohn, Yongdai Kim

2021Neural Computation18 citationsDOI

Abstract

Recent theoretical studies proved that deep neural network (DNN) estimators obtained by minimizing empirical risk with a certain sparsity constraint can attain optimal convergence rates for regression and classification problems. However, the sparsity constraint requires knowing certain properties of the true model, which are not available in practice. Moreover, computation is difficult due to the discrete nature of the sparsity constraint. In this letter, we propose a novel penalized estimation method for sparse DNNs that resolves the problems existing in the sparsity constraint. We establish an oracle inequality for the excess risk of the proposed sparse-penalized DNN estimator and derive convergence rates for several learning tasks. In particular, we prove that the sparse-penalized estimator can adaptively attain minimax convergence rates for various nonparametric regression problems. For computation, we develop an efficient gradient-based optimization algorithm that guarantees the monotonic reduction of the objective function.

Topics & Concepts

MinimaxEstimatorConstraint (computer-aided design)Mathematical optimizationRegularization (linguistics)ComputationArtificial neural networkOracleMathematicsEmpirical risk minimizationConvergence (economics)Rate of convergenceComputer scienceAlgorithmArtificial intelligenceGeometrySoftware engineeringStatisticsEconomic growthChannel (broadcasting)Computer networkEconomicsSparse and Compressive Sensing TechniquesStatistical Methods and InferenceStochastic Gradient Optimization Techniques
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