Recurrent Neural Network to Estimate Intake Manifold O2 Concentration in a Diesel Engine

2020 20th International Conference on Control, Automation and Systems (ICCAS) Pub Date : 2020-10-13 DOI:10.23919/ICCAS50221.2020.9268307

L. Ventura, S. Malan

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引用次数: 1

Abstract

Emission regulations are becoming more and more stringent, especially on NOx pollutants, making diesel engines with their embedded control systems more and more complex. To ensure a correct and clean engine functioning, all the control strategies related to aftertreatment, fuel injection and air-path have to exploit or target the intake manifold O2 concentration. The O2 concentration is strictly related to engine-out NOx emissions and an accurate model, to be implemented in emission control systems, is essential. The paper addresses the modeling of the intake O2 concentration in a turbocharged diesel engine by means of a Recurrent Neural Network with simulation focus and fed with four inputs. The inputs are engine load, engine speed and the position of Exhaust Gas Recirculation and Variable Geometry Turbochargers valves. Training and validation data are generated using the engine simulation tool GT-Power implementing a detailed model of the engine while the training procedure is performed in MATLAB environment through NNSYSID toolbox. The performances of the obtained model are satisfactory in different tests and the model is able to account for the engine nonlinearities during transients.

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递归神经网络估算柴油机进气歧管氧浓度

排放法规越来越严格，特别是对氮氧化物污染物的排放，使得柴油机及其嵌入式控制系统变得越来越复杂。为了确保发动机正常、清洁地工作，所有与后处理、燃油喷射和空气路径相关的控制策略都必须利用或以进气歧管的O2浓度为目标。O2浓度与发动机排出的NOx排放量密切相关，因此在排放控制系统中实施精确的模型至关重要。本文采用具有仿真焦点和四输入的递归神经网络对增压柴油机进气氧气浓度进行建模。输入是发动机负荷、发动机转速以及废气再循环和可变几何涡轮增压器阀门的位置。使用发动机仿真工具GT-Power实现发动机的详细模型生成训练和验证数据，通过NNSYSID工具箱在MATLAB环境下执行训练过程。所建立的模型在不同的试验中表现出令人满意的性能，能很好地解释发动机瞬态非线性。

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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2020 20th International Conference on Control, Automation and Systems (ICCAS)

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