Mitigating Over-smoothing in Transformers via Regularized Nonlocal Functionals
Abstract
Transformers have achieved remarkable success in a wide range of natural language processing and computer vision applications. However, the representation capacity of a deep transformer model is degraded due to the over-smoothing issue in which the token representations become identical when the model's depth grows. In this work, we show that self-attention layers in transformers minimize a functional which promotes smoothness, thereby causing token uniformity. We then propose a novel regularizer that penalizes the norm of the difference between the smooth output tokens from self-attention and the input tokens to preserve the fidelity of the tokens. Minimizing the resulting regularized energy functional, we derive the Neural Transformer with a Regularized Nonlocal Functional (NeuTRENO), a novel class of transformer models that can mitigate the over-smoothing issue. We empirically demonstrate the advantages of NeuTRENO over the baseline transformers and state-of-the-art methods in reducing the over-smoothing of token representations on various practical tasks, including object classification, image segmentation, and language modeling.
Keywords
Cite
@article{arxiv.2312.00751,
title = {Mitigating Over-smoothing in Transformers via Regularized Nonlocal Functionals},
author = {Tam Nguyen and Tan M. Nguyen and Richard G. Baraniuk},
journal= {arXiv preprint arXiv:2312.00751},
year = {2023}
}
Comments
24 papes