Artificial Intelligence Strategies for the Development of Robust Virtual Sensors: An Industrial Case for Transient Particle Emissions in a High-Performance Engine

IF 1.1 Q3 TRANSPORTATION SCIENCE & TECHNOLOGY
Leonardo Pulga, Claudio Forte, Alfio Siliato, Emanuele Giovannardi, Roberto Tonelli, Ioannis Kitsopanidis, Gian Marco Bianchi
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引用次数: 0

Abstract

The use of data-driven algorithms for the integration or substitution of current production sensors is becoming a consolidated trend in research and development in the automotive field. Due to the large number of variables and scenarios to consider; however, it is of paramount importance to define a consistent methodology accounting for uncertainty evaluations and preprocessing steps, that are often overlooked in naïve implementations. Among the potential applications, the use of virtual sensors for the analysis of solid emissions in transient cycles is particularly appealing for industrial applications, considering the new legislations scenario and the fact that, to our best knowledge, no robust models have been previously developed. In the present work, the authors present a detailed overview of the problematics arising in the development of a virtual sensor, with particular focus on the transient particulate number (diameter &lt;10 nm) emissions, overcome by leveraging data-driven algorithms and a profound knowledge of the underlying physical limitations. The workflow has been tested and validated using a complete dataset composed of more than 30 full driving cycles obtained from industrial experimentations, underlying the importance of each step and its possible variations. The final results show that a reliable model for transient particulate number emissions is possible and the accuracy reached is compatible with the intrinsic cycle to cycle variability of the phenomenon, while ensuring control over the quality of the predicted values, in order to provide valuable insight for the actions to perform.
开发鲁棒虚拟传感器的人工智能策略:高性能发动机瞬态粒子排放的工业案例
使用数据驱动算法集成或替代当前的生产传感器正在成为汽车领域研究和开发的巩固趋势。由于需要考虑的变量和场景较多;然而,定义一个考虑不确定性评估和预处理步骤的一致方法是至关重要的,这在naïve实现中经常被忽视。在潜在的应用中,使用虚拟传感器分析瞬态循环中的固体排放对工业应用特别有吸引力,考虑到新的立法情景和事实,据我们所知,以前没有开发出强大的模型。在目前的工作中,作者详细概述了虚拟传感器开发中出现的问题,特别关注瞬态颗粒数(直径< 10nm)发射,通过利用数据驱动算法和对潜在物理限制的深刻了解来克服。该工作流程已使用由工业实验获得的30多个完整驾驶循环组成的完整数据集进行了测试和验证,从而揭示了每个步骤的重要性及其可能的变化。最终结果表明,建立可靠的瞬态颗粒数排放模型是可能的,所达到的精度与该现象的内在周期到周期变异性相兼容,同时确保对预测值质量的控制,以便为执行行动提供有价值的见解。
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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来源期刊
SAE International Journal of Engines
SAE International Journal of Engines TRANSPORTATION SCIENCE & TECHNOLOGY-
CiteScore
2.70
自引率
8.30%
发文量
38
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