Nonlinear Advantage: Trained Networks Might Not Be As Complex as You Think
November 30, 2022 ยท Declared Dead ยท ๐ International Conference on Machine Learning
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Authors
Christian H. X. Ali Mehmeti-Gรถpel, Jan Disselhoff
arXiv ID
2211.17180
Category
cs.LG: Machine Learning
Cross-listed
cs.CV
Citations
6
Venue
International Conference on Machine Learning
Last Checked
4 months ago
Abstract
We perform an empirical study of the behaviour of deep networks when fully linearizing some of its feature channels through a sparsity prior on the overall number of nonlinear units in the network. In experiments on image classification and machine translation tasks, we investigate how much we can simplify the network function towards linearity before performance collapses. First, we observe a significant performance gap when reducing nonlinearity in the network function early on as opposed to late in training, in-line with recent observations on the time-evolution of the data-dependent NTK. Second, we find that after training, we are able to linearize a significant number of nonlinear units while maintaining a high performance, indicating that much of a network's expressivity remains unused but helps gradient descent in early stages of training. To characterize the depth of the resulting partially linearized network, we introduce a measure called average path length, representing the average number of active nonlinearities encountered along a path in the network graph. Under sparsity pressure, we find that the remaining nonlinear units organize into distinct structures, forming core-networks of near constant effective depth and width, which in turn depend on task difficulty.
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