混合LSTM + 1DCNN方法预测内燃机扭矩

Federico Ricci, Luca Petrucci, Francesco Mariani
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引用次数: 1

摘要

目前,人们正在研究创新的解决方案,以管理不断增长的数据量,从而优化内燃机的性能。机器学习方法已被证明是信号预测的宝贵工具,因为它们具有实时性和成本效益。其中,由长短期记忆(LSTM)和一维卷积神经网络(1DCNNs)组成的架构已成为取代物理传感器的一种非常有前途和有效的选择。该体系结构将LSTM检测信号较小片段中的模式和关系的能力与1DCNNs检测信号较大片段中的模式和关系的能力相结合。这项工作的目的是评估替代一个专门用于计算火花点火发动机提供的扭矩的物理设备的可行性。在瞬态操作条件下进行的测试活动中,使用来自现场的信号对建议的架构进行了训练和测试。结果表明,LSTM + 1DCNN特别适合于具有相当可变性的信号预测。它不断优于其他用于比较的架构,平均误差百分比小于2%,证明了该架构取代物理传感器的能力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Hybrid LSTM + 1DCNN Approach to Forecasting Torque Internal Combustion Engines
Innovative solutions are now being researched to manage the ever-increasing amount of data required to optimize the performance of internal combustion engines. Machine learning approaches have shown to be a valuable tool for signal prediction due to their real-time and cost-effective deployment. Among them, the architecture consisting of long short-term memory (LSTM) and one-dimensional convolutional neural networks (1DCNNs) has emerged as a highly promising and effective option to replace physical sensors. This architecture combines the capacity of LSTM to detect patterns and relationships in smaller segments of a signal with the ability of 1DCNNs to detect patterns and relationships in larger segments of a signal. The purpose of this work is to assess the feasibility of substituting a physical device dedicated to calculating the torque supplied by a spark-ignition engine. The suggested architecture was trained and tested using signals from the field during a test campaign conducted under transient operating conditions. The results reveal that LSTM + 1DCNN is particularly well suited for signal prediction with considerable variability. It constantly outperforms other architectures used for comparison, with average error percentages of less than 2%, proving the architecture’s ability to replace physical sensors.
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