Only sparsity based loss function for learning representations
This work addresses representation learning in neural networks, offering a novel loss function for improving efficiency, but it appears incremental as it builds on existing sparsity and regularization concepts.
The paper investigates the emergence of sparse representations in neural networks, attributing it to data distributed along non-linear manifolds, and introduces a new sparsity-based loss function for regularization or unsupervised learning.
We study the emergence of sparse representations in neural networks. We show that in unsupervised models with regularization, the emergence of sparsity is the result of the input data samples being distributed along highly non-linear or discontinuous manifold. We also derive a similar argument for discriminatively trained networks and present experiments to support this hypothesis. Based on our study of sparsity, we introduce a new loss function which can be used as regularization term for models like autoencoders and MLPs. Further, the same loss function can also be used as a cost function for an unsupervised single-layered neural network model for learning efficient representations.