TY - JOUR
T1 - On Nonlinear Model Predictive Control for Energy-Efficient Torque-Vectoring
AU - Parra, Alberto
AU - Tavernini, Davide
AU - Gruber, Patrick
AU - Sorniotti, Aldo
AU - Zubizarreta, Asier
AU - Perez, Joshue
N1 - Publisher Copyright:
© 1967-2012 IEEE.
PY - 2021/1
Y1 - 2021/1
N2 - A recently growing literature discusses the topics of direct yaw moment control based on model predictive control (MPC), and energy-efficient torque-vectoring (TV) for electric vehicles with multiple powertrains. To reduce energy consumption, the available TV studies focus on the control allocation layer, which calculates the individual wheel torque levels to generate the total reference longitudinal force and direct yaw moment, specified by higher level algorithms to provide the desired longitudinal and lateral vehicle dynamics. In fact, with a system of redundant actuators, the vehicle-level objectives can be achieved by distributing the individual control actions to minimize an optimality criterion, e.g., based on the reduction of different power loss contributions. However, preliminary simulation and experimental studies – not using MPC – show that further important energy savings are possible through the appropriate design of the reference yaw rate. This paper presents a nonlinear model predictive control (NMPC) implementation for energy-efficient TV, which is based on the concurrent optimization of the reference yaw rate and wheel torque allocation. The NMPC cost function weights are varied through a fuzzy logic algorithm to adaptively prioritize vehicle dynamics or energy efficiency, depending on the driving conditions. The results show that the adaptive NMPC configuration allows stable cornering performance with lower energy consumption than a benchmarking fuzzy logic TV controller using an energy-efficient control allocation layer.
AB - A recently growing literature discusses the topics of direct yaw moment control based on model predictive control (MPC), and energy-efficient torque-vectoring (TV) for electric vehicles with multiple powertrains. To reduce energy consumption, the available TV studies focus on the control allocation layer, which calculates the individual wheel torque levels to generate the total reference longitudinal force and direct yaw moment, specified by higher level algorithms to provide the desired longitudinal and lateral vehicle dynamics. In fact, with a system of redundant actuators, the vehicle-level objectives can be achieved by distributing the individual control actions to minimize an optimality criterion, e.g., based on the reduction of different power loss contributions. However, preliminary simulation and experimental studies – not using MPC – show that further important energy savings are possible through the appropriate design of the reference yaw rate. This paper presents a nonlinear model predictive control (NMPC) implementation for energy-efficient TV, which is based on the concurrent optimization of the reference yaw rate and wheel torque allocation. The NMPC cost function weights are varied through a fuzzy logic algorithm to adaptively prioritize vehicle dynamics or energy efficiency, depending on the driving conditions. The results show that the adaptive NMPC configuration allows stable cornering performance with lower energy consumption than a benchmarking fuzzy logic TV controller using an energy-efficient control allocation layer.
KW - Torque-vectoring
KW - Nonlinear model predictive control
KW - Powertrain power loss
KW - Tire slip power loss
KW - Reference yaw rate
KW - Control allocation
KW - Weight adaptation
KW - Torque-vectoring
KW - Nonlinear model predictive control
KW - Powertrain power loss
KW - Tire slip power loss
KW - Reference yaw rate
KW - Control allocation
KW - Weight adaptation
UR - http://www.scopus.com/inward/record.url?scp=85100908238&partnerID=8YFLogxK
U2 - 10.1109/tvt.2020.3022022
DO - 10.1109/tvt.2020.3022022
M3 - Article
SN - 0018-9545
VL - 70
SP - 173
EP - 188
JO - IEEE Transactions on Vehicular Technology
JF - IEEE Transactions on Vehicular Technology
IS - 1
M1 - 9186728
ER -