TY - GEN
T1 - Torque vectoring control for fully electric sae cars
AU - De Pascale, Valentina
AU - Lenzo, Basilio
AU - Farroni, Flavio
AU - Timpone, Francesco
AU - Zhang, Xudong
N1 - Publisher Copyright:
© Springer Nature Switzerland AG 2020.
PY - 2020
Y1 - 2020
N2 - Fully electric vehicles with individually controlled powertrains can achieve significantly enhanced vehicle response, in particular by means of Torque Vectoring Control (TVC). This paper presents a TVC strategy for a Formula SAE (FSAE) fully electric vehicle, the “T-ONE” car designed by “UninaCorse E-team” of the University of Naples Federico II, featuring four in-wheel motors. A Matlab-Simulink double-track vehicle model is implemented, featuring non-linear (Pacejka) tyres. The TVC strategy consists of: (i) a reference generator that calculates the target yaw rate in real time based on the current values of steering wheel angle and vehicle velocity, in order to follow a desired optimal understeer characteristic; (ii) a high-level controller which generates the overall traction/braking force and yaw moment demands based on the accelerator/brake pedal and on the error between the target yaw rate and the actual yaw rate; (iii) a control allocator which outputs the reference torques for the individual wheels. A driver model was implemented to work out the brake/accelerator pedal inputs and steering wheel angle input needed to follow a generic trajectory. In a first implementation of the model, a circular trajectory was adopted, consistently with the “skid-pad” test of the FSAE competition. Results are promising as the vehicle with TVC achieves up to ͌9% laptime savings with respect to the vehicle without TVC, which is deemed significant and potentially crucial in the context of the FSAE competition.
AB - Fully electric vehicles with individually controlled powertrains can achieve significantly enhanced vehicle response, in particular by means of Torque Vectoring Control (TVC). This paper presents a TVC strategy for a Formula SAE (FSAE) fully electric vehicle, the “T-ONE” car designed by “UninaCorse E-team” of the University of Naples Federico II, featuring four in-wheel motors. A Matlab-Simulink double-track vehicle model is implemented, featuring non-linear (Pacejka) tyres. The TVC strategy consists of: (i) a reference generator that calculates the target yaw rate in real time based on the current values of steering wheel angle and vehicle velocity, in order to follow a desired optimal understeer characteristic; (ii) a high-level controller which generates the overall traction/braking force and yaw moment demands based on the accelerator/brake pedal and on the error between the target yaw rate and the actual yaw rate; (iii) a control allocator which outputs the reference torques for the individual wheels. A driver model was implemented to work out the brake/accelerator pedal inputs and steering wheel angle input needed to follow a generic trajectory. In a first implementation of the model, a circular trajectory was adopted, consistently with the “skid-pad” test of the FSAE competition. Results are promising as the vehicle with TVC achieves up to ͌9% laptime savings with respect to the vehicle without TVC, which is deemed significant and potentially crucial in the context of the FSAE competition.
KW - Driver model
KW - Fully electric vehicle Formula SAE
KW - Torque Vectoring Control
UR - http://www.scopus.com/inward/record.url?scp=85084011356&partnerID=8YFLogxK
U2 - 10.1007/978-3-030-41057-5_87
DO - 10.1007/978-3-030-41057-5_87
M3 - Conference contribution
AN - SCOPUS:85084011356
SN - 9783030410568
T3 - Lecture Notes in Mechanical Engineering
SP - 1075
EP - 1083
BT - Proceedings of 24th AIMETA Conference 2019
A2 - Carcaterra, Antonio
A2 - Graziani, Giorgio
A2 - Paolone, Achille
PB - Springer Science and Business Media Deutschland GmbH
T2 - 24th Conference of the Italian Association of Theoretical and Applied Mechanics, AIMETA 2019
Y2 - 15 September 2019 through 19 September 2019
ER -