Franz Philipp, Bereck, Christian Hippolyt, Bartsch, Limei, Jin, Andreas, Mertens, Rüdiger-Albert, Eichel, Christoph, Scheurer, Josef, Granwehr
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Thereby DRT can provide the number of distinguishable features based solely on the EIS data, without a priori knowledge of the response of the investigated system. It is demonstrated that such a 'lossless' DRT inversion is possible if the local noise amplitude is considered, which requires a weighted DRT procedure and a method to estimate the frequency dependent noise amplitude. A noise estimate to determine the necessary weights was obtained using multiple EIS acquisitions of the same battery at identical state-of-charge. Alternatively, it is shown that Gaussian process regression (GPR) is capable of estimating an equivalent weighting matrix from a single data set as a prerequisite for automatized weighted DRT inversion without user intervention. The obtained DRT spectrum is then used for the selection of an equivalent circuit model, its initial parametrization, and setting of constraints. The robustness and reliability of this technique is tested numerically using a simple digital twin model. 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引用次数: 0
摘要
电化学阻抗光谱法(EIS)是表征电池、燃料电池或电解槽等电化学系统最广泛使用的方法之一。弛豫时间分布(DRT)是一种通过使用合适的核进行解卷积来简化 EIS 数据的技术,而等效电路建模(ECM)则是通过拟合用户选择的函数来表征所研究的系统。理想情况下,DRT 拟合的残差应代表无系统残差的随机白噪声,因此这一分析步骤不会丢失任何有用数据。因此,DRT 可以仅根据 EIS 数据提供可区分特征的数量,而无需先验地了解所研究系统的响应。研究表明,如果考虑到局部噪声振幅,这种 "无损" DRT 反演是可能的,这就需要一个加权 DRT 程序和一种估算与频率相关的噪声振幅的方法。通过在相同充电状态下对同一电池进行多次 EIS 采集,获得了用于确定必要权重的噪声估计值。另外,研究还表明,高斯过程回归 (GPR) 能够从单个数据集中估算出等效加权矩阵,这是自动加权 DRT 反演的先决条件,无需用户干预。获得的 DRT 频谱可用于选择等效电路模型、初始参数化和设置约束条件。该技术的稳健性和可靠性通过一个简单的数字孪生模型进行了数值测试。最后,通过所研究的电池,讨论了将 DRT 和 ECM 结合使用,可以实现对电化学系统过程更贴近物理的描述。
Weighted distribution of relaxation time analysis of battery impedance spectra using Gaussian process regression for noise estimation
Electrochemical impedance spectroscopy (EIS) is one of the most widely deployed methods to characterise electrochemical systems such as batteries, fuel cells or electrolyzers. The distribution of relaxation times (DRT) represents a technique to simplify EIS data by deconvolution with a suitable kernel, while with equivalent circuit modelling (ECM) a user-selected function is fitted to characterize the investigated system. Ideally, the residuals of a DRT fit should represent random white noise without systematic residuals, hence no useful data is lost by this analysis step. Thereby DRT can provide the number of distinguishable features based solely on the EIS data, without a priori knowledge of the response of the investigated system. It is demonstrated that such a 'lossless' DRT inversion is possible if the local noise amplitude is considered, which requires a weighted DRT procedure and a method to estimate the frequency dependent noise amplitude. A noise estimate to determine the necessary weights was obtained using multiple EIS acquisitions of the same battery at identical state-of-charge. Alternatively, it is shown that Gaussian process regression (GPR) is capable of estimating an equivalent weighting matrix from a single data set as a prerequisite for automatized weighted DRT inversion without user intervention. The obtained DRT spectrum is then used for the selection of an equivalent circuit model, its initial parametrization, and setting of constraints. The robustness and reliability of this technique is tested numerically using a simple digital twin model. Eventually, by means of the investigated battery it is discussed that using a combination of DRT and ECM, a more physically relevant description of processes in an electrochemical system can be achieved.