Lithium Ion Battery Health Prediction via Variable Mode Decomposition and Deep Learning Network With Self-Attention Mechanism

Yang, Ge; Zhang, Fusheng; Ren, Yong

doi:10.3389/fenrg.2022.810490

Cited by 18 publications

(7 citation statements)

References 34 publications

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“…Yu et al (2022) presented an improved Euclidean distance method and a cosine similarity method from the perspective of similarity for online diagnosis of multi-fault inseries connected battery packs. Ge et al (2022) established a comprehensive lithium-ion battery SOH estimation method based on variable mode decomposition, particle filter, and long short-term memory with a self-attention mechanism. Hu and Zhao (2022) presented a RUL prognostics method for lithium-ion batteries based on the wavelet threshold denoising and transformer neural network.…”

Section: Frontiers In Energy Researchmentioning

confidence: 99%

“…Lithium-ion battery manufacturers must conduct extensive life testing to obtain the design formulations, structural parameters, and operating environments that maximize battery life. Predicting the life of newly developed batteries based on the full-life degradation data of similar batteries (reference batteries) can significantly reduce product development time and cost (Finegan and Cooper, 2019;Fan et al, 2021b;Ge et al, 2022). Therefore, the remaining useful life (RUL) prognostics of lithium-ion batteries are beneficial for properly using and maintaining batteries and assisting in designing new products during the R&D phase.…”

Section: Introductionmentioning

confidence: 99%

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Remaining useful life prognostics of lithium-ion batteries based on a coordinate reconfiguration of degradation trajectory and multiple linear regression

Chen

Li²,

Cui³

et al. 2023

Front. Energy Res.

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Lithium battery has been widely applied as new energy to cope with pressures in both form environment and energy. The remaining useful life (RUL) prognostics of lithium-ion batteries have become more critical. Convenient battery life prediction allows early detection of performance deficiencies to help maintain the battery system promptly. This paper proposes a RUL prognostics model of lithium-ion batteries based on a coordinate reconfiguration of degradation trajectory and multiple linear regression. First, a new sampling rule is used to reconfigure the coordinates of degradation data of new batteries and truncated similar batteries. Then, the relationship between similar and new lithium-ion batteries is established by using the reconfiguration data. Moreover, a new RUL prognostics model based on a coordinate reconfiguration of degradation trajectory and multiple linear regression is established by considering the influence of time-varying factors, which can improve prediction accuracy with small sample data and significantly reduce product development time and cost.

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Section: Frontiers In Energy Researchmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Remaining useful life prognostics of lithium-ion batteries based on a coordinate reconfiguration of degradation trajectory and multiple linear regression

Chen

Li²,

Cui³

et al. 2023

Front. Energy Res.

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“…Research on artificial neural networks continues to advance and has significantly progressed in various areas (Chen et al , 2020; Wang et al , 2021; Ge et al , 2022a; He et al , 2022; Zhou et al , 2022). In response to the problem of environmental pollution caused by aviation, scholars have developed a neural network prediction model for aviation emissions to assess the impact of aviation emissions on the environmental climate (Ge et al , 2022b). For the problem of thermal deformation caused by the temperature of machine tool processing, scholars use neural networks to build prediction models to predict accurately and compensate for the thermal deformation error of machine tools (Yan and Yang, 2009; Li et al , 2019; Zhang et al , 2019).…”

Section: Introductionmentioning

confidence: 99%

Research on ERS point registration of large-size measurement field based on neural network non-uniform temperature field

Huang

2023

RIA

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Purpose Large size of aircraft assembly tooling structure and complex measurement environment exist. The laid enhanced reference points (ERS) are subject to a combination of nonuniform temperature fields and measurement errors, resulting in increased measurement registration errors. In view of the nonuniform temperature field and measurement errors affecting the ERS point registration problem, the purpose of this paper is to propose a neural network-based ERS point registration compensation method for large-size measurement fields under a nonuniform temperature field. Design/methodology/approach The approach is to collect ERS point information and temperature data, normalize the collected data to complete the data structure design and complete the construction of the neural network prediction model by data training. The data learning is performed to complete the prediction model construction, and the prediction model is used to complete the compensation analysis of ERS points. Finally, the algorithm is verified through experiments and engineering practice. Findings Experimental results show that the proposed neural network-based ERS point prediction and compensation method for nonuniform temperature fields effectively predicts ERS point deformation under nonuniform temperature fields compared with the conventional method. After the compensation analysis, the registration error is effectively reduced to improve registration accuracy. Reducing the combined effect of environmental nonuniform temperature field and measurement error has apparent advantages. Originality/value The method reduces the registration error caused by combining a nonuniform temperature field and measurement error. It can be used for aircraft assembly site prediction and registration error compensation analysis, which is essential to improve measurement accuracy further.

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“…On the other hand, the real health degradation of the system is often subjected to phenomena such as random disturbances and degradation regeneration [17,18]. Since the original sensor signals are usually non-stationary and non-linear, the health degradation curves obtained through sensor fusion have degradation regeneration and instantaneous mutations issues which may result in large errors in the similarity-matching process.…”

Section: Introductionmentioning

confidence: 99%

“…The technique has received increasing attention because it solves the problems of endpoint effects in EMD. Ge et al [17] proposed an integrated prediction method based on VMD and long short-term memory networks with selfattention mechanisms to mine the degradation information for battery. However, VMD requires a human-defined modal number k, which has a strong effect on the accuracy of the results.…”

Section: Introductionmentioning

confidence: 99%

A similarity-based remaining useful life prediction method using multimodal degradation features and adjusted cosine similarity

Kong

Zeng

et al. 2023

Meas. Sci. Technol.

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When a large amount of full life-cycle data are available, similarity-based methods are the preferred method for remaining useful life (RUL) prediction due to their reliability and accuracy. Traditional similarity-based RUL prediction methods use a single model and single-scale degradation features, which are incapable of fully capturing the degradation behavior of the system. Additionally, the similarity of spatial orientation is neglected in the similarity-matching process. To fill these research gaps, a novel method is developed based on multimodal degradation features and adjusted cosine similarity to tackle complex-system remaining useful life prediction in this paper. Complete ensemble empirical mode decomposition with adaptive noise is employed to decouple global degradation and random fluctuations in run-to-failure sensor data. Slow feature analysis is utilized to obtain local degradation features, and residual terms are used as global degradation features. Then, multimodal degradation features are transformed into one-dimensional health degradation indicators by bidirectional gated recurrent unit autoencoder. An adjusted cosine similarity is developed to estimate the matching similarity between the test degradation curve and the training degradation curve. The proposed scheme captures the time-varying multimodal degradation behavior which eliminates the effects of random fluctuations while retaining important degradation differences information. The designed scheme is evaluated on the C-MAPSS dataset and the results illustrate the competitiveness and effectiveness of the proposed method.

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Lithium Ion Battery Health Prediction via Variable Mode Decomposition and Deep Learning Network With Self-Attention Mechanism

Cited by 18 publications

References 34 publications

Remaining useful life prognostics of lithium-ion batteries based on a coordinate reconfiguration of degradation trajectory and multiple linear regression

Remaining useful life prognostics of lithium-ion batteries based on a coordinate reconfiguration of degradation trajectory and multiple linear regression

Research on ERS point registration of large-size measurement field based on neural network non-uniform temperature field

A similarity-based remaining useful life prediction method using multimodal degradation features and adjusted cosine similarity

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