Multi-Source Feature Fusion and Entropy Feature Lightweight Neural Network for Constrained Multi-State Heterogeneous Iris Recognition

Liu, Shuai; Liu, Yuanning; Zhu, Xiaodong; Huo, Guang; Cui, Jingwei; Zhang, Qixian; Zukang, Wu; Li, Xinlong; Wang, Chaoqun

doi:10.1109/access.2020.2981555

Cited by 9 publications

(1 citation statement)

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“…CNN-based FDD has the following advantages: (i) Industrial system data has multi-source heterogeneity [41]- [44]. The input of CNN can be time series [45]- [47], spectrogram [48], [49], and images [50]- [52], which is suitable for multisource information processing [41], [53]; (ii) Complex PV systems are often accompanied by random strong magnetic interference, high temperatures. The features extracted by CNN have translation invariance [54], [55], which increases the robustness of the diagnosis algorithm and improves the generalization ability of CNN; (iii) The data that can characterize the faults in PV systems is often submerged in massive real-time data.…”

Section: A Convolutional Neural Network Based Fault Diagnosismentioning

confidence: 99%

Deep Learning-Based Fault Diagnosis of Photovoltaic Systems: A Comprehensive Review and Enhancement Prospects

Mansouri¹,

Trabelsi

Nounou

et al. 2021

IEEE Access

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Photovoltaic (PV) systems are subject to failures during their operation due to the aging effects and external/environmental conditions. These faults may affect the different system components such as PV modules, connection lines, converters/inverters, which can lead to a decrease in the efficiency, performance, and further system collapse. Thus, a key factor to be taken into consideration in high-efficiency grid-connected PV systems is the fault detection and diagnosis (FDD). The performance of the FDD method depends mainly on the quality of the extracted features including real-time changes, phase changes, trend changes, and faulty modes. Thus, the data representation learning is the core stage of intelligent FDD techniques. Recently, due to the enhancement of computing capabilities, the increase of the big data use, and the development of effective algorithms, the deep learning (DL) tool has witnessed a great success in data science. Therefore, this paper proposes an extensive review on deep learning based FDD methods for PV systems. After a brief description of the DL-based strategies, techniques for diagnosing PV systems proposed in recent literature are overviewed and analyzed to point out their differences, advantages and limits. Future research directions towards the improvement of the performance of the DL-based FDD techniques are also discussed. This review paper aims to systematically present the development of DLbased FDD for PV systems and provide guidelines for future research in the field.

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