An independently controllable active steering system for maximizing the handling performance limits of road vehicles

Farazandeh, Azadeh; Ahmed, A. K. W.; Rakheja, Subhash

doi:10.1177/0954407014560419

Cited by 17 publications

(10 citation statements)

References 21 publications

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“…Considering weight transfer on each wheel improves the vehicle stability during turning and braking on lowtraction road surfaces. Farazandeh et al 11…”

Section: Song and Yang 10 Conventional Car Load Transfer With Brakingmentioning

confidence: 99%

Analysis of cornering response and stability of electrified heavy commercial road vehicles with regenerative braking

Subramaniyam

Subramanian

2019

Proceedings of the Institution of Mechanical Engineers, Part D:

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Additional powertrain components and regenerative braking are two important factors that may affect the performance and stability of electrified vehicle cornering. The location of additional components affects the vehicle’s center of gravity (CG) position and thereby the stability of the vehicle. As regenerative braking is possible only on driven wheels, the brake force distribution between front and rear wheels may not follow the ideal brake force distribution curve. Hence, applying maximum regenerative braking during cornering may affect vehicle stability, and this has motivated the analysis presented in this paper. The scope of this research work includes obtaining a model for the regenerative brake system, which was then used to analyze the heavy commercial road vehicle lateral dynamic response during combined cornering and regenerative braking. A sensitivity study was carried out regarding variations in center of gravity, longitudinal speed, and tire–road traction coefficient [Formula: see text]. The IPG TruckMaker® vehicle simulation software running in a hardware-in-loop experimental system was used to study the heavy road vehicle cornering performance. The results showed that applying braking on a constant radius path required correction in the steering input to follow the desired path. However, the amount of steering correction required during regenerative braking was higher than that with conventional friction braking. Moreover, applying maximum regenerative braking at higher longitudinal speeds on snowy roads and split- µ roads has a higher impact on vehicle cornering performance compared with that on dry roads. Furthermore, a co-operative braking strategy with an optimum brake force sharing between regenerative braking and friction braking was developed to improve the electrified heavy commercial road vehicle’s cornering stability and handling performance during cornering and braking.

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“…Considering weight transfer on each wheel improves the vehicle stability during turning and braking on lowtraction road surfaces. Farazandeh et al 11…”

Section: Song and Yang 10 Conventional Car Load Transfer With Brakingmentioning

confidence: 99%

Analysis of cornering response and stability of electrified heavy commercial road vehicles with regenerative braking

Subramaniyam

Subramanian

2019

Proceedings of the Institution of Mechanical Engineers, Part D:

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“…The paper 35 puts forward a method to divide the working area of AFS and DYC system according to the linear area of the curve of tire lateral force changing with the tire lateral slip angle, which will be used in this paper as well.…”

Section: Coordinate Strategymentioning

confidence: 99%

“…The measurement method is to take the tire lateral slip angle corresponding to the point where the slope of the tire lateral force curve starts to decline with the change of tire lateral slip angle as the critical value of the linear-transition area. According to the reference, 35 the tire lateral slip angle corresponds to the point where the slope drops to 30% as the critical value of the transition-saturation area.…”

Section: Coordinate Strategymentioning

confidence: 99%

Coordinated control of active front steering and active disturbance rejection sliding mode-based DYC for 4WID-EV

Feng

Wang

2020

Measurement and Control

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The four-wheel independent driven electric vehicle (4WID-EV) can easily realize the four-wheel independent drive, which is convenient for the development and design of the direct yaw moment control system (DYC). Based on the theory of ADRC and the sliding mode control, a new type of DYC controller coordinated with the AFS controller using PID method is designed for the 4WID-EV in this paper. The coordinated control work area is divided according to the tire lateral force linear area. An improved particle swarm optimization algorithm which introduces linear decreasing inertia weight and annealing strategy is adopted to obtain the coordination work weight. The effectiveness of the DYC controller is verified by the Simulink simulation. It also shows that the performance is further improved after the coordinated control.

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“…Active steering control systems control the yaw dynamics of vehicles by adding or subtracting an additional steering angle to the front wheels and/or the rear wheels. 7 Although active steering control systems do not have the weaknesses of direct yaw moment control systems, they cannot guarantee an acceptable performance in non-linear operational region of vehicles (e.g. high-lateral-acceleration manoeuvres).…”

Section: Introductionmentioning

confidence: 99%

Developing an active variable-wheelbase system for enhancing the vehicle dynamics

Soltani

Goodarzi

Shojaiefard

et al. 2017

Proceedings of the Institution of Mechanical Engineers, Part D:

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In order to enhance the vehicle dynamics, this paper presents a novel and innovative yaw moment control system in which the longitudinal positions of the wheels are individually controlled. For this purpose, the proposed concept is analytically and numerically studied first, and it is shown that the method can considerably modify the inherent characteristics of a vehicle, such as the handling and the steerability. This system can generate a stabilizing yaw moment, without any considerable changes in the total lateral force and the total longitudinal force of the vehicle. Finally, a comprehensive vehicle model together with an intelligent fuzzy control strategy are developed to evaluate the effectiveness of the active variable-wheelbase system in different driving conditions. Based on the simulation results, this system has the potential to be considered as a new alternative technique for vehicle dynamics control in the future.

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An independently controllable active steering system for maximizing the handling performance limits of road vehicles

Cited by 17 publications

References 21 publications

Analysis of cornering response and stability of electrified heavy commercial road vehicles with regenerative braking

Analysis of cornering response and stability of electrified heavy commercial road vehicles with regenerative braking

Coordinated control of active front steering and active disturbance rejection sliding mode-based DYC for 4WID-EV

Developing an active variable-wheelbase system for enhancing the vehicle dynamics

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