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 controlle...
When dealing with electric vehicles, different powertrain layouts can be exploited. Among them, the ...
Electrification has drastically changed the way road car are designed. The floor of the vehicle chas...
The benefits of individual wheel torque control, or torque vectoring, in terms of vehicle dynamics b...
Fully electric vehicles with individually controlled powertrains can achieve significantly enhanced ...
Fully electric vehicles with individually controlled powertrains can achieve significantly enhanced ...
© 2012 WEVA.This paper deals with the description of current and future vehicle technology related t...
This paper deals with the description of current and future vehicle technology related to yaw moment...
Electric vehicles with multiple motors permit continuous direct yaw moment control, also called torq...
In electric vehicles with multiple motors, the individual wheel torque control, i.e., the so-called ...
A key feature achievable by electric vehicles with multiple motors is torque-vectoring. Many control...
Common vehicle always experience energy loss during cornering manoeuver. Thus, to ensure it did not ...
The safety benefits of torque-vectoring control of electric vehicles with multiple drivetrains are w...
When dealing with electric vehicles, different powertrain layouts can be exploited. Among them, the ...
Electrification has drastically changed the way road car are designed. The floor of the vehicle chas...
The benefits of individual wheel torque control, or torque vectoring, in terms of vehicle dynamics b...
Fully electric vehicles with individually controlled powertrains can achieve significantly enhanced ...
Fully electric vehicles with individually controlled powertrains can achieve significantly enhanced ...
© 2012 WEVA.This paper deals with the description of current and future vehicle technology related t...
This paper deals with the description of current and future vehicle technology related to yaw moment...
Electric vehicles with multiple motors permit continuous direct yaw moment control, also called torq...
In electric vehicles with multiple motors, the individual wheel torque control, i.e., the so-called ...
A key feature achievable by electric vehicles with multiple motors is torque-vectoring. Many control...
Common vehicle always experience energy loss during cornering manoeuver. Thus, to ensure it did not ...
The safety benefits of torque-vectoring control of electric vehicles with multiple drivetrains are w...
When dealing with electric vehicles, different powertrain layouts can be exploited. Among them, the ...
Electrification has drastically changed the way road car are designed. The floor of the vehicle chas...
The benefits of individual wheel torque control, or torque vectoring, in terms of vehicle dynamics b...