According to the World Health Organization,about 50 million people worldwide suffer from epilepsy.The detection and treatment of epilepsy face great challenges.Electroencephalogram(EEG)is a significant research object...According to the World Health Organization,about 50 million people worldwide suffer from epilepsy.The detection and treatment of epilepsy face great challenges.Electroencephalogram(EEG)is a significant research object widely used in diagnosis and treatment of epilepsy.In this paper,an adaptive feature learning model for EEG signals is proposed,which combines Huber loss function with adaptive weight penalty term.Firstly,each EEG signal is decomposed by intrinsic time-scale decomposition.Secondly,the statistical index values are calculated from the instantaneous amplitude and frequency of every component and fed into the proposed model.Finally,the discriminative features learned by the proposed model are used to detect seizures.Our main innovation is to consider a highly flexible penalization based on Huber loss function,which can set different weights according to the influence of different features on epilepsy detection.Besides,the new model can be solved by proximal alternating direction multiplier method,which can effectively ensure the convergence of the algorithm.The performance of the proposed method is evaluated on three public EEG datasets provided by the Bonn University,Childrens Hospital Boston-Massachusetts Institute of Technology,and Neurological and Sleep Center at Hauz Khas,New Delhi(New Delhi Epilepsy data).The recognition accuracy on these two datasets is 98%and 99.05%,respectively,indicating the application value of the new model.展开更多
In recent years,subsynchronous control interaction(SSCI)has frequently taken place in renewable-connected power systems.To counter this issue,utilities have been seeking tools for fast and accurate identification of S...In recent years,subsynchronous control interaction(SSCI)has frequently taken place in renewable-connected power systems.To counter this issue,utilities have been seeking tools for fast and accurate identification of SSCI events.The main challenges of SSCI monitoring are the time-varying nature and uncertain modes of SSCI events.Accordingly,this paper presents a simple but effective method that takes advantage of intrinsic time-scale decomposition(ITD).The main purpose is to improve the accuracy and robustness of ITD by incorporating the least-squares method.Results show that the proposed method strikes a good balance between dynamic performance and estimation accuracy.More importantly,the method does not require any prior information,and its performance is therefore not affected by the frequency constitution of the SSCI.Comprehensive comparative studies are conducted to demonstrate the usefulness of the method through synthetic signals,electromagnetic temporary program(EMTP)simulations,and field-recorded SSCI data.Finally,real-time simulation tests are conducted to show the feasibility of the method for real-time monitoring.展开更多
针对滚动轴承早期故障信号具有周期性冲击的特点和被强噪声淹没而难以提取的问题,提出了一种基于固有时间尺度分解(Intrinsic Time Scale Decomposition,ITD)与稀疏编码收缩(Sparse Coding Shrinkage,SCS)集成的轴承故障特征提取方法(...针对滚动轴承早期故障信号具有周期性冲击的特点和被强噪声淹没而难以提取的问题,提出了一种基于固有时间尺度分解(Intrinsic Time Scale Decomposition,ITD)与稀疏编码收缩(Sparse Coding Shrinkage,SCS)集成的轴承故障特征提取方法(命名为ITD-SCS)。ITD能自适应地将振动信号分解成若干固有旋转分量(Proper Rotation,PR),选择有效的PR分量突显信号的冲击特征。进一步采用奇异值分解(Singular Value Decomposition,SVD)对每一有效PR实施滤噪作为SCS的前置滤噪单元以提高信号的稀疏性。最后,通过SCS利用极大似然估计方法提取合成信号中的冲击特征。将ITD-SCS应用于轴承内圈故障仿真信号和外圈实际故障振动信号的实验结果表明,ITD-SCS能有效提取强背景噪声下的轴承故障信号的冲击特征。展开更多
基金Supported by National Natural Science Foundation of China(Grant Nos.11701144,11971149)Henan Province Key and Promotion Special(Science and Technology)Project(Grant No.212102310305).
文摘According to the World Health Organization,about 50 million people worldwide suffer from epilepsy.The detection and treatment of epilepsy face great challenges.Electroencephalogram(EEG)is a significant research object widely used in diagnosis and treatment of epilepsy.In this paper,an adaptive feature learning model for EEG signals is proposed,which combines Huber loss function with adaptive weight penalty term.Firstly,each EEG signal is decomposed by intrinsic time-scale decomposition.Secondly,the statistical index values are calculated from the instantaneous amplitude and frequency of every component and fed into the proposed model.Finally,the discriminative features learned by the proposed model are used to detect seizures.Our main innovation is to consider a highly flexible penalization based on Huber loss function,which can set different weights according to the influence of different features on epilepsy detection.Besides,the new model can be solved by proximal alternating direction multiplier method,which can effectively ensure the convergence of the algorithm.The performance of the proposed method is evaluated on three public EEG datasets provided by the Bonn University,Childrens Hospital Boston-Massachusetts Institute of Technology,and Neurological and Sleep Center at Hauz Khas,New Delhi(New Delhi Epilepsy data).The recognition accuracy on these two datasets is 98%and 99.05%,respectively,indicating the application value of the new model.
基金supported in part by the National Natural Science Foundation of China(No.51907133)in part by the Fundamental Research Funds for the Central Universities(No.YJ201911).
文摘In recent years,subsynchronous control interaction(SSCI)has frequently taken place in renewable-connected power systems.To counter this issue,utilities have been seeking tools for fast and accurate identification of SSCI events.The main challenges of SSCI monitoring are the time-varying nature and uncertain modes of SSCI events.Accordingly,this paper presents a simple but effective method that takes advantage of intrinsic time-scale decomposition(ITD).The main purpose is to improve the accuracy and robustness of ITD by incorporating the least-squares method.Results show that the proposed method strikes a good balance between dynamic performance and estimation accuracy.More importantly,the method does not require any prior information,and its performance is therefore not affected by the frequency constitution of the SSCI.Comprehensive comparative studies are conducted to demonstrate the usefulness of the method through synthetic signals,electromagnetic temporary program(EMTP)simulations,and field-recorded SSCI data.Finally,real-time simulation tests are conducted to show the feasibility of the method for real-time monitoring.
文摘针对滚动轴承早期故障信号具有周期性冲击的特点和被强噪声淹没而难以提取的问题,提出了一种基于固有时间尺度分解(Intrinsic Time Scale Decomposition,ITD)与稀疏编码收缩(Sparse Coding Shrinkage,SCS)集成的轴承故障特征提取方法(命名为ITD-SCS)。ITD能自适应地将振动信号分解成若干固有旋转分量(Proper Rotation,PR),选择有效的PR分量突显信号的冲击特征。进一步采用奇异值分解(Singular Value Decomposition,SVD)对每一有效PR实施滤噪作为SCS的前置滤噪单元以提高信号的稀疏性。最后,通过SCS利用极大似然估计方法提取合成信号中的冲击特征。将ITD-SCS应用于轴承内圈故障仿真信号和外圈实际故障振动信号的实验结果表明,ITD-SCS能有效提取强背景噪声下的轴承故障信号的冲击特征。