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Jiuhe Wang

Bio: Jiuhe Wang is an academic researcher from Changchun University. The author has contributed to research in topics: Train & Computer science. The author has an hindex of 3, co-authored 5 publications receiving 34 citations.

Papers
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Journal Article•DOI•
22 Dec 2020-Entropy
TL;DR: In this article, the authors present a comprehensive review of these qualitative approaches from both theoretical and practical aspects, and present some of the latest results of the qualitative fault diagnosis in high-speed trains.
Abstract: For ensuring the safety and reliability of high-speed trains, fault diagnosis (FD) technique plays an important role. Benefiting from the rapid developments of artificial intelligence, intelligent FD (IFD) strategies have obtained much attention in the field of academics and applications, where the qualitative approach is an important branch. Therefore, this survey will present a comprehensive review of these qualitative approaches from both theoretical and practical aspects. The primary task of this paper is to review the current development of these qualitative IFD techniques and then to present some of the latest results. Another major focus of our research is to introduce the background of high-speed trains, like the composition of the core subsystems, system structure, etc., based on which it becomes convenient for researchers to extract the diagnostic knowledge of high-speed trains, where the purpose is to understand how to use these types of knowledge. By reasonable utilization of the knowledge, it is hopeful to address various challenges caused by the coupling among subsystems of high-speed trains. Furthermore, future research trends for qualitative IFD approaches are also presented.

44 citations

Journal Article•DOI•
Chao Cheng1, Jiuhe Wang1, Zhijie Zhou, Wanxiu Teng, Zhongbo Sun1, Bangcheng Zhang1 •
TL;DR: The result shows BRB-mr model has stronger diagnostic ability to identify faults and it has a certain engineering application value to be extended to other complex system fault diagnosis.
Abstract: Fault diagnosis is a key way to improve the efficient, safe and stable operation of high-speed trains. This paper proposes a fault diagnosis method based on belief rule base with mixed reliability (BRB-mr). Different from the traditional BRB, this method considers two kinds of interference factors that affect the observation data in engineering practice, including the performance of sensors and the influence of external environment, and we quantify them as static reliability and dynamic reliability of attributes in BRB. In order to integrate two kinds of reliability factors into the reasoning of BRB, a discount method is developed based on Dempster-Shafer theory (D-S theory), which is helpful for more accurate diagnosis. In this paper, the effectiveness and practicability of the method are verified by a single fault of the running gear, and the supplementary numerical data verified its feasibility in multiple fault mode diagnosis. Then this method is compared with traditional methods. The result shows BRB-mr model has stronger diagnostic ability to identify faults and it has a certain engineering application value to be extended to other complex system fault diagnosis.

17 citations

Journal Article•DOI•
TL;DR: A health status prediction method based on the belief rule base (BRB) for the running gear system is proposed and the results show that the proposed model can help to accurately predict the health status of theRunning gear system.
Abstract: The running gear is a vital component of a high-speed train to ensure operation safety. Accurately predicting the future health status of the running gear is significant to keep the reliability and safety of trains. It is difficult to predict the future health status based on the analytical model of the running gear system because of its complexity and coupling. Moreover, the fault data are a minor part of tremendous data in the running and monitoring process of a high-speed train, which obstructs accurately predicting the health status based on a data-driven method. To solve the above problems, this paper proposes a health status prediction method based on the belief rule base (BRB) for the running gear system. First, a failure mechanism is analyzed to confirm the fault characteristics, which can represent the health status of the running gear system. Second, in order to avoid the limitations of a single sensor acquisition, such as a lack of comprehensiveness and robustness, singular value decomposition is used to achieve multisensory information fusion. The fused features are used as the input to the health status prediction model. Data fusion is a way to improve the precision of the health status prediction in the model input. Then, this model based on the BRB is established using the fault data and expert knowledge. During the process of prediction, the subjectivity of experts makes the initial BRB imprecise, so a projection constrained covariance matrix adaptive evolution strategy algorithm is needed to optimize the initial parameters and improve the accuracy of the proposed model. Finally, a case study for the running gear system is carried out to verify the effectiveness and accuracy of the proposed model. The results show that the proposed model can help to accurately predict the health status of the running gear system.

14 citations

Journal Article•DOI•
TL;DR: In this paper, a multidiscounted belief rule base (MBRB) is proposed to evaluate the health status of high-speed trains, which can reduce the negative influence of cognitive uncertainties on system assessment from another perspective.
Abstract: The emergence of large-scale engineering and macro engineering promotes the development of large-scale complex electromechanical systems (LCESs). The LCES complexity of structures and failure mechanisms makes it difficult to achieve the aim of health management and fault diagnosis of such systems. One of the reasons is lacking detailed consideration of various uncertainties from the process of system assessment. Belief rule base (BRB) shows advantages in modeling nonlinear complex systems under the uncertainty environment. However, the current BRB-based work only focuses on optimizing the initial parameters to deal with the impact of cognitive uncertainty, and issues, such as monitoring and environmental uncertainties, are not considered. Thus, this article proposes the multidiscounted BRB (MBRB) to evaluate the health status of LCESs. Different from traditional BRB, MBRB can reduce the negative influence of cognitive uncertainties on system assessment from another perspective, the so-called expert reliability discount model. In addition, monitoring and environmental uncertainties are also considered in MBRB modeling. Three uncertainties can be quantified by statistical models, and they can be integrated into MBRB by combining with evidence discount theory. Due to the treatment of these uncertainties, MBRB can provide accurate results. In comparison with traditional methods, the proposed method shows superior performance in the health assessment of high-speed trains.

9 citations

Journal Article•DOI•
TL;DR: In this article , a real-time health status prediction framework based on a multi-layer belief rule base with priority scheduling strategies for running gears is proposed, which can predict the health status of running gears with much accuracy in real time.
Abstract: The health status of the running gear in high-speed trains changes dynamically with time in a complete life cycle. Running gear systems composed of many coupled components are complex, and health statuses of which are difficult to predict in real time through a traditional health status prediction scheme. Lately, belief rule base (BRB), which is able to combine quantitative information and expert knowledge, has shown excellent expression in modeling complex systems. In the procedure of health status prediction, expert expertise can sufficiently enhance the accuracy and efficiency of this model. Therefore, this paper puts forwards a real-time health status prediction framework based on a multi-layer BRB with priority scheduling strategies for running gears. In the first-layer BRB, a time-series prediction model of multiple module BRB considering complete features is established.In the second-layer model, grey relation analysis (GRA) is employed in priority scheduling strategies of features. The third-layer BRB is used for assessing the health status of running gears by combining the features. In addition, the initial parameters of all module BRB given by experts may not be precise. Accordingly, the initial parameters in the BRB are updated by the recursive algorithm online. Finally, the proposed method is tested on the testing platform in running gears. The results make it clear the proposed method can predict the health status of running gears with much accuracy in real time.

5 citations


Cited by
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Journal Article•DOI•
TL;DR: In this article , the authors systematically review and categorize most of the mainstream FDD methods for high-speed trains and analyze the characteristic of observations from sensors equipped in traction systems.
Abstract: Recently, to ensure the reliability and safety of high-speed trains, detection and diagnosis of faults (FDD) in traction systems have become an active issue in the transportation area over the past two decades. Among these FDD methods, data-driven designs, that can be directly implemented without a logical or mathematical description of traction systems, have received special attention because of their overwhelming advantages. Based on the existing data-driven FDD methods for traction systems in high-speed trains, the first objective of this paper is to systematically review and categorize most of the mainstream methods. By analyzing the characteristic of observations from sensors equipped in traction systems, great challenges which may prevent successful FDD implementations on practical high-speed trains are then summarized in detail. Benefiting from theoretical developments of data-driven FDD strategies, instructive perspectives on this topic are further elaborately conceived by the integration of model-based FDD issues, system identification techniques, and new machine learning tools, which provide several promising solutions to FDD strategies for traction systems in high-speed trains.

96 citations

Journal Article•DOI•
TL;DR: In this paper , a sound-based diagnosis method for railway point machines (RPMs) is presented, where the sound signals are preprocessed using empirical mode decomposition (EMD) and the first 15 intrinsic mode functions (IMFs) are extracted.
Abstract: Contactless fault diagnosis is one of the most important technique for fault identification of equipment. Based on the idea of contactless fault diagnosis, this paper presents a sound-based diagnosis method for railway point machines (RPMs). First, the sound signals are preprocessed using empirical mode decomposition (EMD). Entropy, time-domain and frequency-domain statistical parameters of the first 15 intrinsic mode functions (IMFs) are then extracted. Second, a two-stage feature selection strategy blending Filter method and Wrapper method is proposed, which can significantly reduce the dimension of features and select the optimal features. The superiority and effectiveness of the proposed feature selection strategy are verified by comparing with other feature selection methods. Third, a weighted majority voting (WMV)-based ensemble classifier optimized using particle swarm optimization (PSO) is developed and compared with single classifiers. And the ensemble patterns are discussed to select the most optimal ensemble pattern. The average diagnosis accuracies of 10 repeated trails of reverse-normal and normal-reverse switching processes reach 99% and 99.93%, respectively, which indicates the effectiveness and feasibility of the proposed method.

50 citations

Journal Article•DOI•
22 Dec 2020-Entropy
TL;DR: In this article, the authors present a comprehensive review of these qualitative approaches from both theoretical and practical aspects, and present some of the latest results of the qualitative fault diagnosis in high-speed trains.
Abstract: For ensuring the safety and reliability of high-speed trains, fault diagnosis (FD) technique plays an important role. Benefiting from the rapid developments of artificial intelligence, intelligent FD (IFD) strategies have obtained much attention in the field of academics and applications, where the qualitative approach is an important branch. Therefore, this survey will present a comprehensive review of these qualitative approaches from both theoretical and practical aspects. The primary task of this paper is to review the current development of these qualitative IFD techniques and then to present some of the latest results. Another major focus of our research is to introduce the background of high-speed trains, like the composition of the core subsystems, system structure, etc., based on which it becomes convenient for researchers to extract the diagnostic knowledge of high-speed trains, where the purpose is to understand how to use these types of knowledge. By reasonable utilization of the knowledge, it is hopeful to address various challenges caused by the coupling among subsystems of high-speed trains. Furthermore, future research trends for qualitative IFD approaches are also presented.

44 citations

Journal Article•DOI•
TL;DR: An enhanced FDD architecture using the modified principal component analysis and broad learning system is developed in this article and, based on the proposed data-driven design, fast and accurate FDD can be achieved without requirements for mathematical models or control mechanism of high-speed trains.
Abstract: Faults happen inevitably in traction systems and thus place the security of the whole high-speed train at risk. In order to improve the safety and reliability of high-speed trains, this article deals with fault detection and diagnosis (FDD) problem for traction systems. Because of high sampling frequency of equipped sensors, FDD strategies in the supervision system of high-speed trains should be of enough high computation efficiency, which is a great bottleneck for artificial intelligence-based FDD methods. For reducing the computational load while maintaining the satisfactory diagnostic accuracy, an enhanced FDD architecture using the modified principal component analysis and broad learning system is developed in this article. Based on the proposed data-driven design whose core is to extract fault information, fast and accurate FDD can be achieved without requirements for mathematical models or control mechanism of high-speed trains. The effectiveness and feasibility of the proposed online design are illustrated on the traction control platform of high-speed trains.

25 citations

Posted Content•
TL;DR: Simulates the pignistic probability transformation (PPT) process based on the idea of fractal, making the PPT process and the information volume lost during transformation more intuitive, and proposes a new belief entropy called Fractal-based (FB) entropy, which is the first time to apply fractal idea in belief entropy.
Abstract: The total uncertainty measurement of basic probability assignment (BPA) in evidence theory has always been an open issue. Although many scholars have put forward various measures and requirements of bodies of evidence (BoE), none of them are widely recognized. So in order to express the uncertainty in evidence theory, transforming basic probability assignment (BPA) into probability distribution is a widely used method, but all the previous methods of probability transformation are directly allocating focal elements in evidence theory to their elements without specific transformation process. Based on above, this paper simulates the pignistic probability transformation (PPT) process based on the idea of fractal, making the PPT process and the information volume lost during transformation more intuitive. Then apply this idea to the total uncertainty measure in evidence theory. A new belief entropy called Fractal-based (FB) entropy is proposed, which is the first time to apply fractal idea in belief entropy. After verification, the new entropy is superior to all existing total uncertainty measurements.

25 citations