Jun Zhou scite author profile

Network pruning is an important research field aiming at reducing computational costs of neural networks. Conventional approaches follow a fixed paradigm which first trains a large and redundant network, and then determines which units (e.g., channels) are less important and thus can be removed. In this work, we find that pre-training an over-parameterized model is not necessary for obtaining the target pruned structure. In fact, a fully-trained over-parameterized model will reduce the search space for the pruned structure. We empirically show that more diverse pruned structures can be directly pruned from randomly initialized weights, including potential models with better performance. Therefore, we propose a novel network pruning pipeline which allows pruning from scratch with little training overhead. In the experiments for compressing classification models on CIFAR10 and ImageNet datasets, our approach not only greatly reduces the pre-training burden of traditional pruning methods, but also achieves similar or even higher accuracy under the same computation budgets. Our results facilitate the community to rethink the effectiveness of existing techniques used for network pruning.

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Improving Transferability of Adversarial Patches on Face Recognition with Generative Models

Xiao¹,

Gao

et al. 2021

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Uncertainty estimation for stereo matching based on evidential deep learning

Wang

Zhang

et al. 2022

Pattern Recognition

139

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A future intelligent traffic system with mixed autonomous vehicles and human-driven vehicles

Chen

Sun

Zhou

et al. 2020

Information Sciences

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Cross-Domain Recommendation: Challenges, Progress, and Prospects

Zhu¹,

Wang

Chen³

et al. 2021

116

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To address the long-standing data sparsity problem in recommender systems (RSs), cross-domain recommendation (CDR) has been proposed to leverage the relatively richer information from a richer domain to improve the recommendation performance in a sparser domain. Although CDR has been extensively studied in recent years, there is a lack of a systematic review of the existing CDR approaches. To fill this gap, in this paper, we provide a comprehensive review of existing CDR approaches, including challenges, research progress, and prospects. Specifically, we first summarize existing CDR approaches into four types, including single-target CDR, single-target multi-domain recommendation (MDR), dual-target CDR, and multi-target CDR. We then present the definitions and challenges of these CDR approaches. Next, we propose a full-view categorization and new taxonomies on these approaches and report their research progress in detail. In the end, we share several promising prospects in CDR.

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Jun Zhou

Pruning from Scratch

Improving Transferability of Adversarial Patches on Face Recognition with Generative Models

Uncertainty estimation for stereo matching based on evidential deep learning

A future intelligent traffic system with mixed autonomous vehicles and human-driven vehicles

Cross-Domain Recommendation: Challenges, Progress, and Prospects

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