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基于电池测试平台的智能控制技术综合实验设计OA

Comprehensive experimental design of intelligent control technology based on a battery testing platform

中文摘要英文摘要

为深化学生对智能控制技术理论的理解,提升其工程应用能力,在实验设计中引入电池测试平台,将电池建模、智能算法设计与仿真及实物验证融入电池测试工程场景.通过"数据采集—理论建模—算法设计—结果优化"的闭环实验流程,系统提升学生的建模能力、算法应用能力和问题解决能力.针对传统实验依赖开源数据集、缺乏实际系统案例的局限,该实验设计使学生能够利用电池测试平台获得实验数据,设计粒子群优化算法辨识系统模型参数,通过扩展卡尔曼滤波算法和数据驱动方法进行荷电状态估计并进行加权融合.实验结果表明,加权融合方法的平均绝对误差相较于单独的方法分别提高了 16%和 47%.该实验设计旨在使学生提高动手能力,拓宽分析问题思路,为将来成为合格的工程技术人才打好基础.

[Objective]This study aims to develop a comprehensive experimental framework for an intelligent control technology course by introducing a battery testing platform.The experiment integrates battery modeling,intelligent algorithm design and simulation,and experimental validation within an engineering-oriented battery testing scenario.This approach addresses the limitations of traditional experiments that rely on open-source datasets and lack practical system-level case studies.This approach systematically improves the modeling,algorithm application,and engineering problem-solving abilities of students.It also enhances the hands-on skills of students,broadens their analytical thinking,and lays a solid foundation for them to become qualified engineering and technical professionals in the future.[Methods]This experimental design implements a closed-loop experimental process of"data acquisition-theoretical modeling-algorithm design-result optimization."Using the NEWARE BTS-4008 battery testing platform,real-time voltage and current data of Panasonic 18 650 batteries are collected under constant-temperature conditions.Based on these data,students establish a second-order RC equivalent circuit model and use the particle swarm optimization(PSO)algorithm for parameter identification.Two different methods are used to estimate the state of charge(SOC):one is the model-based extended Kalman filter(EKF)estimation method,and the other is the data-driven random forest(RF)algorithm.A weighted fusion strategy is used to process the estimates from the two methods,improving the accuracy and robustness of the overall estimation scheme.[Results]The parameters identified using the PSO algorithm can effectively reproduce the terminal voltage curve,proving the accuracy and reliability of the parameters and providing a reliable foundation for subsequent SOC estimation.Under dynamic stress test conditions,the performance of fusion and individual methods was evaluated and compared.Compared with the single method,the mean absolute error of the EKF and RF-weighted fusion methods decreased by 16%and 47%,respectively,the root mean square error decreased by 7%and 48%,respectively,and the coefficient of determination(R2)was closer to 1,proving that the fusion method can overcome the limitations of individual methods and significantly improve estimation performance.[Conclusions]Students collected the necessary data through the experimental platform and constructed a battery model based on course knowledge.They then improved the accuracy of the model by adjusting algorithm parameters.This process enhanced their engineering application and modeling abilities while addressing the gap between theory and practice in traditional teaching.This experimental design overcomes the limitations of single algorithm application,achieving battery SOC estimation through the fusion of the EKF algorithm and data-driven RF methods and further guiding students to perform weighted fusion of the estimation results from the two algorithms.This design helps students understand the applicable scenarios,advantages,and limitations of different intelligent algorithms and breaks the rigid thinking of traditional single-solution approaches by integrating real engineering objects and multiple technical paths.It cultivates innovative thinking by encouraging students to analyze problems from multiple dimensions and integrate technical solutions,effectively meeting the training goals of engineering and technical talent development.In the future,the experimental scenarios can be further expanded to continuously improve the depth and breadth of course teaching and provide practical teaching support for talent cultivation in the field of intelligent control.

李俊红;华亮;徐一鸣

南通大学 电气与自动化学院,江苏 南通 226019南通大学 电气与自动化学院,江苏 南通 226019南通大学 电气与自动化学院,江苏 南通 226019

信息技术与安全科学

电池测试平台锂离子电池智能控制技术荷电状态估计参数辨识

battery testing platformlithium-ion batteryintelligent control technologystate of charge estimationparameter identification

《实验技术与管理》 2026 (4)

213-219,7

江苏省学位与研究生教育教学改革重点课题(JGKT24_B052)南通大学研究生课程思政示范课程建设项目、南通大学专业学位研究生教学案例库建设项目(JXAL25_05)2025年江苏省高等教育教改研究重点课题(2025JGZD161)中国交通教育研究会2024-2026年度教育科学研究重点课题(JT2024ZD053)

10.16791/j.cnki.sjg.2026.04.026

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