An unsupervised machine-learning technique for the definition of a rule-based control strategy in a complex HEV

Roberto Finesso, E. Spessa, Mattia Venditti
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引用次数: 13

Abstract

An unsupervised machine-learning technique, aimed at the identification of the optimal rule-based control strategy, has been developed for parallel hybrid electric vehicles that feature a torque-coupling (TC) device, a speed-coupling (SC) device or a dual-mode system, which is able to realize both actions. The approach is based on the preliminary identification of the optimal control strategy, which is carried out by means of a benchmark optimizer, based on the deterministic dynamic programming technique, for different driving scenarios. The optimization is carried out by selecting the optimal values of the control variables (i.e., transmission gear and power flow) in order to minimize fuel consumption, while taking into account several constraints in terms of NOx emissions, battery state of charge and battery life consumption. The results of the benchmark optimizer are then processed with the aim of extracting a set of optimal rule-based control strategies, which can be implemented onboard in real-time. The input variables of the rule-based strategy are the vehicle power demand, the vehicle speed and the state of charge of the battery. The method for the rule extraction can be summarized as follows. A clustering algorithm discretizes the input domain (in terms of vehicle power demand, vehicle speed and state of charge of the battery) into a mesh of clusters. The generic rule associated to a specific cluster (i.e., the combination of gear and power flow that has to be actuated) is identified by searching for the control strategy most frequently adopted by the benchmark optimizer within the considered cluster. The optimal mesh of clusters is generated using a genetic algorithm technique. Optimal sets of rules are identified for different driving scenarios. These strategies can then be implemented on-board, provided the mission features are known at the beginning of the trip. The main advantage of the proposed technique is that the definition of the rule-based strategy is derived from a machine learning method and is not based on heuristic techniques.
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基于规则的复杂HEV控制策略定义的无监督机器学习技术
针对具有扭矩耦合(TC)装置、速度耦合(SC)装置或双模系统的并联混合动力汽车,开发了一种无监督机器学习技术,旨在识别基于规则的最优控制策略。该方法基于基于确定性动态规划技术的基准优化器对不同驾驶场景的最优控制策略进行初步辨识。优化是通过选择控制变量(即变速器档位和功率流)的最优值来实现的,以最小化燃油消耗,同时考虑到氮氧化物排放、电池充电状态和电池寿命消耗等几个约束条件。然后对基准优化器的结果进行处理,目的是提取一组基于规则的最优控制策略,该策略可以在机载实时实现。基于规则的策略的输入变量是车辆的功率需求、车速和电池的充电状态。规则提取的方法可以总结如下。聚类算法将输入域(根据车辆的功率需求、车速和电池的充电状态)离散成一个聚类网格。与特定集群相关的一般规则(即,必须被驱动的齿轮和功率流的组合)通过在考虑的集群中搜索基准优化器最常采用的控制策略来确定。采用遗传算法生成聚类的最优网格。针对不同的驾驶场景,确定了最优的规则集。如果在旅行开始时就知道任务特征,那么这些策略就可以在船上实施。提出的技术的主要优点是基于规则的策略的定义来自机器学习方法,而不是基于启发式技术。
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来源期刊
SAE International Journal of Alternative Powertrains
SAE International Journal of Alternative Powertrains TRANSPORTATION SCIENCE & TECHNOLOGY-
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期刊介绍: The SAE International Journal of Alternative Powertrains provides a forum for peer-reviewed scholarly publication of original research and review papers that address challenges and present opportunities in alternative and electric powertrains and propulsion technology. The Journal strives to facilitate discussion between researchers, engineers, academic faculty and students, and industry practitioners working with systems as well as components, and the technological aspects and functions of powertrains and propulsion systems alternative to the traditional combination of internal combustion engine and mechanical transmission. The editorial scope of the Journal includes all technical aspects of alternative propulsion technologies, including, but not limited to, electric drives and electromobility systems, hybrid technology, battery and super-capacitor technology, power electronics, hydraulic drives, energy storage systems for automotive applications, fuel cell technology, and charging and smart grid infrastructures.
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