Your search keyword '"Jia, Lijie"' showing total 3 results

1. Deep network fault diagnosis for imbalanced small-sized samples via a coupled adversarial autoencoder based on the Bayesian method.

Author

Zhang, Xinliang, Wang, Yanqi, Zhou, Yitian, and Jia, Lijie

Subjects

FAULT diagnosis, DATA augmentation, BAYESIAN analysis, DIAGNOSIS methods, DATABASES, STATISTICAL sampling, DATA modeling, DEEP learning

Abstract

Deep network fault diagnosis methods heavily rely on abundant labeled data for effective model training. However, small-sized samples and imbalanced samples often lead to insufficient features, resulting in accuracy degradation and even instability in the diagnosis model. To address this challenge, this paper introduces a coupled adversarial autoencoder (CoAAE) based on the Bayesian method. This model aims to solve the issue of insufficient samples by generating fake samples and integrating them with the original ones. Within the CoAAE framework, the probability density distribution of the original data is captured using an encoder and fake samples are generated by random sampling from this distribution and decoding them. This process is the adversarial interaction between the encoder and a classifier to obtain the prior distribution of the encoder's parameters. The encoder's parameters are updated through the decoder's reconstruction process, leading to the posterior distribution. Concurrently, the decoder is trained to enhance its ability to reconstruct samples accurately. To address the imbalance in the original samples, a parallel coupled network is employed. This network shares the weights of the extraction layer in the encoder, enabling it to learn the joint distribution between fault-related and normal samples. To evaluate the effectiveness of the proposed data augmentation method, experiments were conducted on a bearing database from Case Western Reserve University using ResNet18 as the deep learning diagnosis model representative. The results demonstrate that CoAAE can effectively augment imbalanced datasets and outperform other advanced methods. [ABSTRACT FROM AUTHOR]

Published

2024

2. An adaptive fully convolutional network for bearing fault diagnosis under noisy environments.

Author

Zhang, Xinliang, Liu, Guanlin, Zhou, Yitian, and Jia, Lijie

Subjects

FAULT diagnosis, FEATURE extraction, CONVOLUTIONAL neural networks, NOISE control

Abstract

Intelligent diagnostic algorithms based on convolutional neural networks (CNNs) have shown great potential in diagnosing various conditions. However, accurately and robustly diagnosing faults in noisy situations remains challenging. This study presents an adaptive fully convolutional network (AFCN) for identifying bearing defects in noisy environments. First, we use a novel large kernel convolution method for high-frequency noise reduction and wide-area temporal feature extraction. By utilizing a sequence of stacked residual adaptive convolution blocks, the AFCN achieves a selective emphasis on significant features and adaptive adjustment of feature weights at various convolution scales. The experimental results have shown that the AFCN achieves a diagnostic accuracy of over 90% for the faults in the CWRU dataset under the −8 dB noise and over 77% for the PU dataset in the case of −6 dB noise. The comparison results with five advanced baseline models have demonstrated the superiority of the AFCN in feature extraction, noise immunity, and robustness to the noise environment. The AFCN provides a better adaption to noise interference than conventional CNNs and other advanced adaptive networks. [ABSTRACT FROM AUTHOR]

Published

2024

3. Publisher's Note: "Deep network fault diagnosis for imbalanced small-sized samples via a coupled adversarial autoencoder based on the Bayesian method" [Rev. Sci. Instrum. 95, 055104 (2024)].

Author

Zhang, Xinliang, Wang, Yanqi, Zhou, Yitian, and Jia, Lijie

Subjects

FAULT diagnosis, PUBLISHING, INTERNET publishing

Abstract

This article was originally published online on 2 May 2024 with the second affiliation missing for Yanqi Wang. All affiliations appear correctly above. AIP Publishing apologizes for the error. All online versions of the article were corrected on 8 May 2024; the article is correct as it appears in the printed version of the journal.By Xinliang Zhang; Yanqi Wang; Yitian Zhou and Lijie JiaReported by Author; Author; Author; Author [Extracted from the article]

Published

2024