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Main Authors: Ding, Jingyi, Qi, Chengwen, Wang, Hongfei, Wu, Jianshe, Jiao, Licheng, Guo, Yuwei, Gao, Jian
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2507.17785
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author Ding, Jingyi
Qi, Chengwen
Wang, Hongfei
Wu, Jianshe
Jiao, Licheng
Guo, Yuwei
Gao, Jian
author_facet Ding, Jingyi
Qi, Chengwen
Wang, Hongfei
Wu, Jianshe
Jiao, Licheng
Guo, Yuwei
Gao, Jian
contents Current research has found that some deep neural networks exhibit strong hierarchical self-similarity in feature representation or parameter distribution. However, aside from preliminary studies on how the power-law distribution of weights across different training stages affects model performance,there has been no quantitative analysis on how the self-similarity of hidden space geometry influences model weight optimization, nor is there a clear understanding of the dynamic behavior of internal neurons. Therefore, this paper proposes a complex network modeling method based on the output features of hidden-layer neurons to investigate the self-similarity of feature networks constructed at different hidden layers, and analyzes how adjusting the degree of self-similarity in feature networks can enhance the classification performance of deep neural networks. Validated on three types of networks MLP architectures, convolutional networks, and attention architectures this study reveals that the degree of self-similarity exhibited by feature networks varies across different model architectures. Furthermore, embedding constraints on the self-similarity of feature networks during the training process can improve the performance of self-similar deep neural networks (MLP architectures and attention architectures) by up to 6 percentage points.
format Preprint
id arxiv_https___arxiv_org_abs_2507_17785
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Self-similarity Analysis in Deep Neural Networks
Ding, Jingyi
Qi, Chengwen
Wang, Hongfei
Wu, Jianshe
Jiao, Licheng
Guo, Yuwei
Gao, Jian
Machine Learning
Current research has found that some deep neural networks exhibit strong hierarchical self-similarity in feature representation or parameter distribution. However, aside from preliminary studies on how the power-law distribution of weights across different training stages affects model performance,there has been no quantitative analysis on how the self-similarity of hidden space geometry influences model weight optimization, nor is there a clear understanding of the dynamic behavior of internal neurons. Therefore, this paper proposes a complex network modeling method based on the output features of hidden-layer neurons to investigate the self-similarity of feature networks constructed at different hidden layers, and analyzes how adjusting the degree of self-similarity in feature networks can enhance the classification performance of deep neural networks. Validated on three types of networks MLP architectures, convolutional networks, and attention architectures this study reveals that the degree of self-similarity exhibited by feature networks varies across different model architectures. Furthermore, embedding constraints on the self-similarity of feature networks during the training process can improve the performance of self-similar deep neural networks (MLP architectures and attention architectures) by up to 6 percentage points.
title Self-similarity Analysis in Deep Neural Networks
topic Machine Learning
url https://arxiv.org/abs/2507.17785