各种驱动循环下丰田 Mirai 2 汽车燃料电池-电池混合动力系统动力学的机器学习建模

IF 9.6 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
Adithya Legala , Matthew Kubesh , Venkata Rajesh Chundru , Graham Conway , Xianguo Li
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引用次数: 0

摘要

电动化被认为是交通领域去碳化的关键,而理解现代燃料电池-电池电动混合动力系统的复杂行为并为其建模具有挑战性,特别是对于需要快速周转和快速计算的产品开发和诊断而言。本研究开发了一种新颖的建模方法,利用有监督的机器学习算法,复制 2021 年丰田 Mirai 第二代(Mirai 2)汽车中燃料电池-电池混合动力系统在各种驱动循环下的动态特性。本研究的全部数据是在底盘测功机测试期间,通过在 Mirai 汽车上安装内部数据采集设备和接入 Mirai 控制器区域网络总线收集的。在 15 个系统运行参数的帮助下,设计了一个多输入-多输出、前馈式人工神经网络架构,不仅可以预测燃料电池属性,如平均最低电池电压、冷却液和阴极空气出口温度,还可以预测电池混合动力系统属性,包括锂离子电池组电压和温度。在瞬态和近稳态驾驶条件组合的各种驾驶循环中收集了超过 21,000 个数据点,其中约 15,000 个点用于训练网络,6,000 个点用于评估模型性能。探索了各种数据过滤技术和神经网络校准过程,以调节数据并了解其对模型性能的影响。校准后的神经网络能准确预测混合动力系统的动态,其 R 平方值大于 0.98,证明了机器学习算法在系统开发和诊断方面的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Machine learning modeling for fuel cell-battery hybrid power system dynamics in a Toyota Mirai 2 vehicle under various drive cycles

Machine learning modeling for fuel cell-battery hybrid power system dynamics in a Toyota Mirai 2 vehicle under various drive cycles

Electrification is considered essential for the decarbonization of mobility sector, and understanding and modeling the complex behavior of modern fuel cell-battery electric-electric hybrid power systems is challenging, especially for product development and diagnostics requiring quick turnaround and fast computation. In this study, a novel modeling approach is developed, utilizing supervised machine learning algorithms, to replicate the dynamic characteristics of the fuel cell-battery hybrid power system in a 2021 Toyota Mirai 2nd generation (Mirai 2) vehicle under various drive cycles. The entire data for this study is collected by instrumenting the Mirai vehicle with in-house data acquisition devices and tapping into the Mirai controller area network bus during chassis dynamometer tests. A multi-input - multi-output, feed-forward artificial neural network architecture is designed to predict not only the fuel cell attributes, such as average minimum cell voltage, coolant and cathode air outlet temperatures, but also the battery hybrid system attributes, including lithium-ion battery pack voltage and temperature with the help of 15 system operating parameters. Over 21,0000 data points on various drive cycles having combinations of transient and near steady-state driving conditions are collected, out of which around 15,000 points are used for training the network and 6,000 for the evaluation of the model performance. Various data filtration techniques and neural network calibration processes are explored to condition the data and understand the impact on model performance. The calibrated neural network accurately predicts the hybrid power system dynamics with an R-squared value greater than 0.98, demonstrating the potential of machine learning algorithms for system development and diagnostics.

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来源期刊
Energy and AI
Energy and AI Engineering-Engineering (miscellaneous)
CiteScore
16.50
自引率
0.00%
发文量
64
审稿时长
56 days
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