This paper aims to explore torque optimization control issue in the turning of EV (Electric Vehicles) with motorized wheels for reducing energy consumption in this process. A three-degree-of-freedom (3-DOF) vehicle dynamics model is used to analyze the total longitudinal force of the vehicle and explain the influence of torque vectoring distribution (TVD) on turning resistance. The Genetic Algorithm-Particle Swarm Optimization Hybrid Algorithm (GA-PSO) is used to optimize the torque distribution coefficient offline. Then, a torque optimization control strategy for obtaining minimum turning energy consumption online and a torque distribution coefficient (TDC) table in different cornering conditions are proposed, with the consideration of veh...
Individually-controlled powertrains of fully electric vehicles present an opportunity to enhance the...
A large number of studies have been conducted on the dynamics control of electric vehicles or on the...
This document presents a study about the possibility of increasing the energy efficiency of electric...
In electric vehicles with multiple motors, the individual wheel torque control, i.e., the so-called ...
Common vehicle always experience energy loss during cornering manoeuver. Thus, to ensure it did not ...
This article proposes an energy-efficiency strategy based on the optimization of driving patterns fo...
The wheel driving torque on four-wheel-drive electric vehicles (4WDEVs) can be modulated precisely a...
The paper discusses novel computationally efficient torque distribution strategies for electric vehi...
Automotive applications often experience conflicting-objective optimization problems focusing on per...
In order to improve the electrical conversion efficiency of an electric tractor motor, a load torque...
The continuous, precise modulation of the driving and braking torque of each wheel is considered to ...
The paper discusses novel computationally efficient torque distribution strategies for electric vehi...
Electric vehicles (EVs) with four individually controlled drivetrains are over-actuated systems, and...
The safety benefits of torque-vectoring control of electric vehicles with multiple drivetrains are w...
Individually-controlled powertrains of fully electric vehicles present an opportunity to enhance the...
A large number of studies have been conducted on the dynamics control of electric vehicles or on the...
This document presents a study about the possibility of increasing the energy efficiency of electric...
In electric vehicles with multiple motors, the individual wheel torque control, i.e., the so-called ...
Common vehicle always experience energy loss during cornering manoeuver. Thus, to ensure it did not ...
This article proposes an energy-efficiency strategy based on the optimization of driving patterns fo...
The wheel driving torque on four-wheel-drive electric vehicles (4WDEVs) can be modulated precisely a...
The paper discusses novel computationally efficient torque distribution strategies for electric vehi...
Automotive applications often experience conflicting-objective optimization problems focusing on per...
In order to improve the electrical conversion efficiency of an electric tractor motor, a load torque...
The continuous, precise modulation of the driving and braking torque of each wheel is considered to ...
The paper discusses novel computationally efficient torque distribution strategies for electric vehi...
Electric vehicles (EVs) with four individually controlled drivetrains are over-actuated systems, and...
The safety benefits of torque-vectoring control of electric vehicles with multiple drivetrains are w...
Individually-controlled powertrains of fully electric vehicles present an opportunity to enhance the...
A large number of studies have been conducted on the dynamics control of electric vehicles or on the...
This document presents a study about the possibility of increasing the energy efficiency of electric...