计算机科学
可识别性
奈奎斯特图
等效电路
介电谱
电阻抗
卷积神经网络
鉴定(生物学)
人工智能
电容感应
模式识别(心理学)
数据挖掘
机器学习
算法
化学
电气工程
操作系统
工程类
物理化学
生物
植物
电压
电化学
电极
作者
Joachim Schaeffer,Paul Gasper,Esteban Garcia-Tamayo,Raymond Gasper,Masaki Adachi,Juan Pablo Gaviria-Cardona,Simon Montoya-Bedoya,Anoushka Bhutani,Andrew Schiek,Rhys E. A. Goodall,Rolf Findeisen,Richard D. Braatz,Simon Engelke
出处
期刊:Journal of The Electrochemical Society
[The Electrochemical Society]
日期:2023-05-25
卷期号:170 (6): 060512-060512
被引量:17
标识
DOI:10.1149/1945-7111/acd8fb
摘要
Analysis of Electrochemical Impedance Spectroscopy (EIS) data for electrochemical systems often consists of defining an Equivalent Circuit Model (ECM) using expert knowledge and then optimizing the model parameters to deconvolute various resistance, capacitive, inductive, or diffusion responses. For small data sets, this procedure can be conducted manually; however, it is not feasible to manually define a proper ECM for extensive data sets with a wide range of EIS responses. Automatic identification of an ECM would substantially accelerate the analysis of large sets of EIS data. We showcase machine learning methods to classify the ECMs of 9,300 impedance spectra provided by QuantumScape for the BatteryDEV hackathon. The best-performing approach is a gradient-boosted tree model utilizing a library to automatically generate features, followed by a random forest model using the raw spectral data. A convolutional neural network using boolean images of Nyquist representations is presented as an alternative, although it achieves a lower accuracy. We publish the data and open source the associated code. The approaches described in this article can serve as benchmarks for further studies. A key remaining challenge is the identifiability of the labels, underlined by the model performances and the comparison of misclassified spectra.
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