Learning Efficient Convolutional Networks through Network Slimming
Zhuang Liu, Jianguo Li, Zhiqiang Shen, Gao Huang, Shoumeng Yan, Changshui Zhang
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The deployment of deep convolutional neural networks (CNNs) in many real world applications is largely hindered by their high computational cost. In this paper, we propose a novel learning scheme for CNNs to simultaneously 1) reduce the model size; 2) decrease the run-time memory footprint; and 3) lower the number of computing operations, without compromising accuracy. This is achieved by enforcing channel-level spar ...
sity in the network in a simple but effective way. Different from many existing approaches, the proposed method directly applies to modern CNN architectures, introduces minimum overhead to the training process, and requires no special software/hardware accelerators for the resulting models. We call our approach network slimming, which takes wide and large networks as input models, but during training insignificant channels are automatically identified and pruned afterwards, yielding thin and compact models with comparable accuracy. We empirically demonstrate the effectiveness of our approach with several state-of-the-art CNN models, including VGGNet, ResNet and DenseNet, on various image classification datasets. For VGGNet, a multi-pass version of network slimming gives a 20× reduction in model size and a 5× reduction in computing operations.
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The deployment of deep convolutional neural networks (CNNs) in many real world applications is largely hindered by their high computational cost.
Implementation Evidence Summary
abhineet123/Deep-Learning-for-Tracking-and-Detection is the closest maintained adjacent implementation (Matches contextual method/domain keyword: deep learning). It is not paper-verified; validate algorithm and evaluation setup against the paper before trusting reported metrics. Community adoption signal: 2508 GitHub stars.
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Utility signals: depth 70/100, grounding 75/100, status medium.
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- abhineet123/Deep-Learning-for-Tracking-and-DetectionAdjacentConfidence: MediumStars: 2,508
Matches contextual method/domain keyword: deep learning
- fengbintu/Neural-Networks-on-SiliconAdjacentConfidence: MediumStars: 2,098
Matches contextual method/domain keyword: deep learning
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Research context
2,589
Citations
60
References
Tasks
Computer science, Convolutional neural network, Memory footprint, Overhead (engineering), Deep learning, Footprint, Process (computing), Computer engineering
Methods
None detected
Domains
Reduction (mathematics), Artificial intelligence, Scheme (mathematics), Machine learning, Computer Vision and Pattern Recognition
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