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GLiT: Neural Architecture Search for Global and Local Image Transformer

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arxiv 2107.02960 v3 pith:TEBF7JPA submitted 2021-07-07 cs.CV

GLiT: Neural Architecture Search for Global and Local Image Transformer

classification cs.CV
keywords searchimagetransformerarchitecturealgorithmlocalmethodmodule
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We introduce the first Neural Architecture Search (NAS) method to find a better transformer architecture for image recognition. Recently, transformers without CNN-based backbones are found to achieve impressive performance for image recognition. However, the transformer is designed for NLP tasks and thus could be sub-optimal when directly used for image recognition. In order to improve the visual representation ability for transformers, we propose a new search space and searching algorithm. Specifically, we introduce a locality module that models the local correlations in images explicitly with fewer computational cost. With the locality module, our search space is defined to let the search algorithm freely trade off between global and local information as well as optimizing the low-level design choice in each module. To tackle the problem caused by huge search space, a hierarchical neural architecture search method is proposed to search the optimal vision transformer from two levels separately with the evolutionary algorithm. Extensive experiments on the ImageNet dataset demonstrate that our method can find more discriminative and efficient transformer variants than the ResNet family (e.g., ResNet101) and the baseline ViT for image classification.

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