Abstract
In this manuscript we address the problem of online optimal control for torque splitting in hybrid electric vehicles that minimises fuel consumption and preserves battery life. We divide the problem into the prediction of the future velocity profile (i.e. driver intention estimation) and the online optimal control of the hybrid powertrain following a Model Predictive Control (MPC) scheme. The velocity prediction is based on a bio-inspired driver model, which is compared on various datasets with two alternative prediction algorithms adopted in the literature. The online optimal control problem addresses both the fuel consumption and the preservation of the battery life using an equivalent cost given the estimated speed profile (i.e. guaranteeing the desired performance). The battery degradation is evaluated by means of a state-of-the-art electrochemical model. Both the predictor and the Energy Management System (EMS) are evaluated in simulation using real driving data divided into 30 driving cycles from 10 drivers characterised by different driving styles. A comparison of the EMS performances is carried out on two different benchmarks based on an offline optimization, in one case on the entire dataset length and in the second on an ideal prediction using two different receding horizon lengths. The proposed online system, composed by the velocity prediction algorithm and the optimal control MPC scheme, shows comparable performances with the previous ideal benchmarks in terms of fuel consumption and battery life preservation. The simulations show that the online approach is able to significantly reduce the capacity loss of the battery, while preserving the fuel saving performances.
Highlights
The impact of mobility on the emissions of greenhouse gases represents a critical reason to make transportation cleaner and more sustainable
The dependency of the fuel efficiency on the knowledge of the future velocity is emphasized by the addition of the aging term, i.e. when the battery aging is minimized in the optimization
In this paper we presented a full energy management system for hybrid electric vehicles
Summary
The impact of mobility on the emissions of greenhouse gases represents a critical reason to make transportation cleaner and more sustainable. Hybrid Electric Vehicles (HEVs) are a step forward to reduce road traffic pollution: one or more electric motors can act as a generator during the braking phase of driving, recovering kinetic energy that would be otherwise wasted as heat Another point of strength is the capability of HEVs to reduce emissions via the redundancy of the power output. EMS typically uses the actual power request, but the knowledge of future torque needed and/or of driver’s intended maneuver might greatly improve the system performance both in terms of energy efficiency [1] and of driver satisfaction. For these reasons, control strategies for EMS and driver’s intention estimation have gained interest in research
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