An accurate and resource-efficient network for surface anomaly detection via enhanced downsampling and activation representation

IF 9.9 1区工程技术 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Advanced Engineering Informatics Pub Date : 2025-09-27 DOI:10.1016/j.aei.2025.103891

Xunkuai Zhou , Xi Chen , Jie Chen , Ben M. Chen

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引用次数: 0

Abstract

In deep learning-based anomaly detection, performance degradation often results from feature loss caused by downsampling and the limited nonlinear representation capacity of conventional activation functions. Moreover, improving detection accuracy often demands substantial computational resources, thereby hindering practical deployment in real-time and resource-constrained collaborative multi-robot inspection settings. To address these challenges, this paper proposes DEANet, a memory-efficient and real-time anomaly detection methodology with four key components, designed to achieve high accuracy at low computational cost. First, a lightweight feature aggregation neck improves feature fusion efficiency while reducing computational overhead. Second, a contextual feature extraction module leverages environmental semantics to enhance both detection and localization accuracy. Third, to alleviate the feature degradation introduced by hierarchical downsampling, two enhancement modules are designed to facilitate a better trade-off between accuracy and computational cost. Fourth, we propose a parameterized activation function (ACLU) that enhances the network’s nonlinear representational capacity. ACLU achieves higher accuracy and demonstrates faster convergence compared to recent advanced activation functions. Experiments on three benchmark datasets confirm that DEANet achieves state-of-the-art accuracy with only 2.8 million parameters, while reducing training data demands by 70%, parameter count by 87.8%, and computational cost by 92.6%, demonstrating its strong efficiency–performance trade-off under resource-constrained conditions. Edge-computing deployment tests validate DEANet’s real-time performance at 52.1 FPS. These results highlight DEANet’s practicality and scalability for deployment in real-world, resource-constrained settings. The source code will be available at https://github.com/chriszxk/surface-detection.git.

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通过增强的下采样和激活表示，为地表异常检测提供了一个准确且资源高效的网络

在基于深度学习的异常检测中，下采样导致的特征丢失和传统激活函数有限的非线性表示能力往往会导致性能下降。此外，提高检测精度往往需要大量的计算资源，从而阻碍了在实时和资源受限的多机器人协作检测环境中的实际部署。为了解决这些挑战，本文提出了DEANet，一种具有四个关键组件的内存高效实时异常检测方法，旨在以低计算成本实现高精度。首先，轻量级的特征聚合颈提高了特征融合效率，同时减少了计算开销。其次，上下文特征提取模块利用环境语义来提高检测和定位的准确性。第三，为了减轻分层下采样带来的特征退化，设计了两个增强模块，以便更好地在精度和计算成本之间进行权衡。第四，我们提出了一个参数化激活函数（ACLU）来增强网络的非线性表示能力。与最近的高级激活函数相比，ACLU实现了更高的精度和更快的收敛速度。在三个基准数据集上的实验证实，DEANet仅用280万个参数就达到了最先进的精度，同时将训练数据需求减少了70%，参数数量减少了87.8%，计算成本减少了92.6%，证明了它在资源受限条件下的强大效率-性能权衡。边缘计算部署测试验证了DEANet在52.1 FPS的实时性能。这些结果突出了DEANet在现实世界中资源受限环境下部署的实用性和可扩展性。源代码可从https://github.com/chriszxk/surface-detection.git获得。

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来源期刊

Advanced Engineering Informatics 工程技术-工程：综合

CiteScore

12.40

自引率

18.20%

发文量

292

审稿时长

45 days

期刊介绍： Advanced Engineering Informatics is an international Journal that solicits research papers with an emphasis on 'knowledge' and 'engineering applications'. The Journal seeks original papers that report progress in applying methods of engineering informatics. These papers should have engineering relevance and help provide a scientific base for more reliable, spontaneous, and creative engineering decision-making. Additionally, papers should demonstrate the science of supporting knowledge-intensive engineering tasks and validate the generality, power, and scalability of new methods through rigorous evaluation, preferably both qualitatively and quantitatively. Abstracting and indexing for Advanced Engineering Informatics include Science Citation Index Expanded, Scopus and INSPEC.