特征提取
计算机科学
断层(地质)
人工智能
模式识别(心理学)
特征(语言学)
噪音(视频)
支持向量机
方位(导航)
传感器融合
残余物
数据挖掘
工程类
算法
语言学
哲学
地震学
地质学
图像(数学)
作者
Zhenzhong Xu,Xu Chen,Yilin Li,Jiangtao Xu
出处
期刊:Sensors
[Multidisciplinary Digital Publishing Institute]
日期:2024-03-11
卷期号:24 (6): 1792-1792
被引量:27
摘要
Aiming at the traditional single sensor vibration signal cannot fully express the bearing running state, and in the high noise background, the traditional algorithm is insufficient for fault feature extraction. This paper proposes a fault diagnosis algorithm based on multi-sensor and hybrid multimodal feature fusion to achieve high-precision fault diagnosis by leveraging the operating state information of bearings in a high-noise environment to the fullest extent possible. First, the horizontal and vertical vibration signals from two sensors are fused using principal component analysis, aiming to provide a more comprehensive description of the bearing's operating condition, followed by data set segmentation. Following fusion, time-frequency feature maps are generated using a continuous wavelet transform for global time-frequency feature extraction. A first diagnostic model is then developed utilizing a residual neural network. Meanwhile, the feature data is normalized, and 28 time-frequency feature indexes are extracted. Subsequently, a second diagnostic model is constructed using a support vector machine. Lastly, the two diagnosis models are integrated to derive the final model through an ensemble learning algorithm fused at the decision level and complemented by a genetic algorithm solution to improve the diagnosis accuracy. Experimental results demonstrate the effectiveness of the proposed algorithm in achieving superior diagnostic performance with a 97.54% accuracy rate.
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