Electric Vehicle Longitudinal Stability Control Based on a New Multimachine Nonlinear Model Predictive Direct Torque Control

Sekour, M.; Hartani, Kada; Merah, Abdelkader

doi:10.1155/2017/4125384

Cited by 18 publications

(12 citation statements)

References 38 publications

(47 reference statements)

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“…For superior ABS performance, the slip ratio should be kept close to the ideal value 15. Tracking performance of the braking force using mean square error is expressed in the following equation 10: (14) The differential equation of PID controlled is [10]: (15) Next, the transfer function to be added to MATLAB/Simulink is as follows [30]: (16) The tracking error is calculated as follows [30]: (17) Modern controllers require signals calculated in digital or discrete time 23. In the Proportional-Integral-Derivative controller (PID) P is related to the error that happens in the present, I show the error collected from the past, and D indicates the predicted upcoming error 1.…”

Section: Fig 5 Brake Dynamic In Simulink For Braking System With Abmentioning

confidence: 99%

Anti-Lock Braking System Components Modelling

Alaboodi*¹,

Algadah²

2019

IJITEE

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Anti-lock braking systems are widely used in modern vehicles and provide safe driving for many different road conditions. Tire skidding occurs unexpectedly as a result of non-linearity in the system. The system behavior can be modelled and simulated using simulation software, which would help to visualize the system behavior. It would lead to obtaining optimum brake performance as well as safe driving. Modelling and simulation methods that can be used with every component of the system are presented. A variety of simulation software has been discussed.

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Section: Fig 5 Brake Dynamic In Simulink For Braking System With Abmentioning

confidence: 99%

Anti-Lock Braking System Components Modelling

Alaboodi*¹,

Algadah²

2019

IJITEE

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“…The final voltage vector suppressing harmonic current of the stator was obtained; thus, the fast dynamic response and good steady performance were kept unchanged. A novel multi-machine robust DTC scheme based on the nonlinear model prediction (NMP) method was proposed [31]. It achieved the acceleration slip regulation (ASR) and anti-lock braking system (ABS) functions of four wheels PMSMs and better driving performance and vehicle stability.…”

Section: Dtcmentioning

confidence: 99%

Review and Development of Electric Motor Systems and Electric Powertrains for New Energy Vehicles

et al. 2021

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This paper presents a review on the recent research and technical progress of electric motor systems and electric powertrains for new energy vehicles. Through the analysis and comparison of direct current motor, induction motor, and synchronous motor, it is found that permanent magnet synchronous motor has better overall performance; by comparison with converters with Si-based IGBTs, it is found converters with SiC MOSFETs show significantly higher efficiency and increase driving mileage per charge. In addition, the pros and cons of different control strategies and algorithms are demonstrated. Next, by comparing series, parallel, and power split hybrid powertrains, the series–parallel compound hybrid powertrains are found to provide better fuel economy. Different electric powertrains, hybrid powertrains, and range-extended electric systems are also detailed, and their advantages and disadvantages are described. Finally, the technology roadmap over the next 15 years is proposed regarding traction motor, power electronic converter and electric powertrain as well as the key materials and components at each time frame.

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“…[23], model predictive control (MPC) shows better traction performance than PID control due to the implementation of the non-linear model. However, MPC needs much more computing resources, which makes its practical application harder [24]. In addition, fuzzy logic is also utilised in some studies to maintain slip ratios by controlling traction torque.…”

Section: Introductionmentioning

confidence: 99%

Acceleration‐based wheel slip control realized with decentralised electric drivetrain systems

Jiang

Sharma

Liu

et al. 2022

IET Electrical Syst in Trans

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Traction control is one of the most important functions in vehicle drivetrain systems. When a vehicle is driven on a low‐friction road surface, loss of traction force can cause the driven wheels to spin. This reduces vehicle acceleration performance and can even cause the driver to lose control of the vehicle. The high bandwidth of electric machine control in electric vehicles gives more possibilities to regulate driving torque on wheels and prevent wheel spin. An acceleration‐based wheel slip control is designed and investigated. Compared to traditional slip‐based traction control, the proposed method does not depend on the estimation of the vehicle speed and only relies on the driven wheel rotational acceleration. The control method is verified using the simulation of an electric vehicle with a decentralised electric drivetrain system. The vehicle and the electric drive are modelled in CarMaker and PLECS, respectively. The simulation results show that the proposed method is able to prevent the driven wheel from spinning when the vehicle is accelerated on an ice road. In addition, the control is fast enough and requires only half a second to reduce the wheel acceleration to a normal range.

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Electric Vehicle Longitudinal Stability Control Based on a New Multimachine Nonlinear Model Predictive Direct Torque Control

Cited by 18 publications

References 38 publications

Anti-Lock Braking System Components Modelling

Anti-Lock Braking System Components Modelling

Review and Development of Electric Motor Systems and Electric Powertrains for New Energy Vehicles

Acceleration‐based wheel slip control realized with decentralised electric drivetrain systems

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