The Optimization Landscape of SGD Across the Feature Learning Strength
Abstract
We consider neural networks (NNs) where the final layer is down-scaled by a fixed hyperparameter γ. Recent work has identified γ as controlling the strength of feature learning. As γ increases, network evolution changes from "lazy" kernel dynamics to "rich" feature-learning dynamics, with a host of associated benefits including improved performance on common tasks. In this work, we conduct a thorough empirical investigation of the effect of scaling γ across a variety of models and datasets in the online training setting. We first examine the interaction of γ with the learning rate η, identifying several scaling regimes in the γ-η plane which we explain theoretically using a simple model. We find that the optimal learning rate η* scales non-trivially with γ. In particular, η* γ2 when γ 1 and η* γ2/L when γ 1 for a feed-forward network of depth L. Using this optimal learning rate scaling, we proceed with an empirical study of the under-explored "ultra-rich" γ 1 regime. We find that networks in this regime display characteristic loss curves, starting with a long plateau followed by a drop-off, sometimes followed by one or more additional staircase steps. We find networks of different large γ values optimize along similar trajectories up to a reparameterization of time. We further find that optimal online performance is often found at large γ and could be missed if this hyperparameter is not tuned. Our findings indicate that analytical study of the large-γ limit may yield useful insights into the dynamics of representation learning in performant models.
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