Title :
Driving control architecture for six-in-wheel-driving and skid-steered series hybrid vehicles
Author :
Jaewon Nah ; Seungjae Yun ; Kyongsu Yi ; Wongun Kim ; Jongbae Kim
Author_Institution :
Grad. Sch. of Convergence Sci. & Technol., Seoul Nat. Univ., Seoul, South Korea
Abstract :
This paper presents a driving control method including torque distribution, slip control and regenerative-hydraulic brake control to maximize maneuverability for six-in-wheel-drive and skid-steered series hybrid vehicles. Wheel torque command to each wheel, to track both net longitudinal force and net yaw moment, is distributed based on control allocation method. Because regenerative brake torque does not satisfy desired deceleration under certain speed condition, hydraulic brake system is controlled to obtain suitable brake force rapidly. The maneuvering performance of the six-wheeled and skid-steered vehicle with the proposed driving controller has been compared to that of an Ackerman-steered vehicle with even-distribution controller via TruckSim & Matlab-Simulink co-simulations.
Keywords :
braking; hydraulic systems; road vehicles; torque control; Ackerman-steered vehicle; Matlab-Simulink cosimulations; control allocation method; distribution controller; driving control architecture; driving control method; driving controller; hydraulic brake system; longitudinal force; net yaw moment; regenerative hydraulic brake control; six-in-wheel-driving; skid-steered series hybrid vehicles; slip control; torque distribution; wheel torque command; Batteries; Force; Mathematical model; Resource management; Torque; Vehicles; Wheels; 5pt italic; list 3–5 keywords from the provided keyword list in 9; separated by commas;
Conference_Titel :
Electric Vehicle Symposium and Exhibition (EVS27), 2013 World
Conference_Location :
Barcelona
DOI :
10.1109/EVS.2013.6914819
