Approximation of Supercapacitor Charging Process Using Fractional Order Transfer Functions

2022 IEEE XVIII International Conference on the Perspective Technologies and Methods in MEMS Design (MEMSTECH) Pub Date : 2022-09-07 DOI:10.1109/MEMSTECH55132.2022.10002930

B. Kopchak, A. Kushnir, L. Kasha, Mykhailo Khai

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Abstract

The expressions of the fractional order transfer functions of the supercapacitor charging process using the most common models of representing their impedance are analytically obtained and the most optimal model for further research is chosen. The calculation of the fractional order transfer function of the supercapacitor charging process with a 1F capacity is carried out, using the averaged data of various experimental studies. Also, the obtained transition process is compared with the experimental one. Experimental studies of transition charging processes of supercapacitors with different capacities (0.22 F, 1.0 F, 4.7 F) are carried out, using a voltage divider without using an operational amplifier. The obtained transition processes are approximated by the use of compact fractional order transfer functions by the particle swarm optimization method. The estimation of the approximation accuracy for different variants of transfer functions in the time domain is performed.

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用分数阶传递函数逼近超级电容器充电过程

用最常用的阻抗表示模型解析得到了超级电容器充电过程中分数阶传递函数的表达式，并选择了最优模型进行进一步研究。利用各种实验研究的平均数据，计算了容量为1F的超级电容器充电过程的分数阶传递函数。并将所得的过渡过程与实验结果进行了比较。实验研究了不同容量(0.22 F, 1.0 F, 4.7 F)超级电容器的过渡充电过程，使用分压器而不使用运算放大器。得到的过渡过程用粒子群优化方法用紧致分数阶传递函数逼近。对时域内不同传递函数的近似精度进行了估计。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 IEEE XVIII International Conference on the Perspective Technologies and Methods in MEMS Design (MEMSTECH)

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