COMPILED: Deep Metric Learning for Defect Classification of Threaded Pipe Connections using Multichannel Partially Observed Functional Data
- URL: http://arxiv.org/abs/2404.03329v3
- Date: Sun, 08 Dec 2024 13:45:24 GMT
- Title: COMPILED: Deep Metric Learning for Defect Classification of Threaded Pipe Connections using Multichannel Partially Observed Functional Data
- Authors: Juan Du, Yukun Xie, Chen Zhang,
- Abstract summary: We focus on defect classification where each sample is represented as partially observed multichannel functional data.<n>The available samples for each defect type are limited and imbalanced.<n>We propose an innovative classification approach named as COMPILED based on deep metric learning.
- Score: 6.688305507010403
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: In modern manufacturing, most products are conforming. Few products are nonconforming with different defect types. The identification of defect types can help further root cause diagnosis of production lines. With the sensing technology development, process variables evolved as time changes, which can be collected in high resolution as multichannel functional data. These functional data have rich information to characterize the process and help identify the defect types. Motivated by a real example from the threaded pipe connection process, we focus on defect classification where each sample is represented as partially observed multichannel functional data. However, the available samples for each defect type are limited and imbalanced. The functional data is partially observed since the pre-connection process before the threaded pipe connection process is unobserved as there is no sensor installed in the production line. Therefore, the defect classification based on imbalanced, multichannel, and partially observed functional data is very important but challenging. To deal with these challenges, we propose an innovative classification approach named as COMPILED based on deep metric learning. The framework leverages the power of deep metric learning to train on imbalanced datasets. A novel neural network structure is proposed to handle multichannel partially observed functional data. The results from a real-world case study demonstrate the superior accuracy of our framework when compared to existing benchmarks.
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