Surface Defect Detection of Heat Sink Based on Lightweight Fully Convolutional Network
Author(s): Yang, KF (Yang, Kaifeng); Liu, YL (Liu, Yuliang); Zhang, SW (Zhang, Shiwen); Cao, JJ (Cao, Jiajian)
Source: IEEE TRANSACTIONS ON INSTRUMENTATION AND MEASUREMENT Volume: 71 Article Number: 2512912 DOI: 10.1109/TIM.2022.3188033 Published: 2022
Abstract: The surface defect detection plays an important role in industrial production and directly affects production efficiency and product quality. In this article, we focus on the surface defect detection of heat sink and propose a method based on a Ghost-SE light U-Net (GSLU-Net). The GSLU-Net is a novel combination of the lightweight convolution module, self-attention mechanism, and fully convolutional network (FCN). It has a symmetrical architecture inspired by the U-Net. By introducing the Ghost module, which can generate feature maps with cheap operations, we reduce the computation cost while maintaining high accuracy. The Ghost module uses an ordinary convolution with small kernels to obtain original feature maps and then a depthwise convolution to generate more feature maps. The squeeze-and-excitation (SE) block is also introduced to improve the representational power of the network and further improve accuracy. It can adaptively recalibrate channelwise feature responses at a slight additional computational cost. Fewer downsampling layers and more skip connections enable this network to retain more location information and have stronger detection capabilities for tiny targets than previous FCNs. The ablation experiments validate that our improvements have played their due role. Then, the comparative experiments demonstrate that our network outperforms the state-of-the-art FCNs. The GSLU-Net reaches an accuracy of 97.96% at a speed of 14.115 ms per image on the dataset of heat sink surface defect, achieving a balance of efficiency and accuracy. The GSLU-Net also outperforms other networks on open datasets, further demonstrating the superiority of the GSLU-Net.
Accession Number: WOS:000838413500011
Author Identifiers:
Author Web of Science ResearcherID ORCID Number
cao, jiajian 0000-0003-2029-5961
ISSN: 0018-9456
eISSN: 1557-9662
Full Text: https://ieeexplore.ieee.org/document/9814089