Research on output power stability control method of EV-DWPT system

Tire longitudinal forces of electrics vehicle with four in-wheel-motors can be adjusted independently. This provides advantages for its stability control. In this paper, an electric vehicle with four in-wheel-motors is taken as the research object. Considering key factors such as vehicle velocity and road adhesion coefficient, the criterion of vehicle stability is studied, based on phase plane of sideslip angle and sideslip-angle rate. To solve the problem that the sideslip angle of vehicles is difficult to measure, an algorithm for estimating the sideslip angle based on extended Kalman filter is designed. The control method for vehicle yaw moment based on sliding-mode control and the distribution method for wheel driving/braking torque are proposed. The distribution method takes the minimum sum of the square for wheel load rate as the optimization objective. Based on Matlab/Simulink and Carsim, a cosimulation model for the stability control of electric vehicles with four in-wheel-motors is built. The accuracy of the proposed stability criterion, the algorithm for estimating the sideslip angle and the wheel torque control method are verified. The relevant research can provide some reference for the development of the stability control for electric vehicles with four in-wheel-motors.

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Visual servoing of dynamic wheeled mobile robots with anti-interference finite-time controllers

Assembly Automation ◽

10.1108/aa-11-2017-157 ◽

2018 ◽

Vol 38 (5) ◽

pp. 558-567 ◽

Cited By ~ 3

Author(s):

Hua Chen ◽

Lei Chen ◽

Qian Zhang ◽

Fei Tong

Keyword(s):

Mobile Robots ◽

Finite Time ◽

Visual Servoing ◽

Control Method ◽

External Disturbance ◽

Nonholonomic Systems ◽

Stability Control ◽

Interference Control ◽

Wheeled Mobile Robots ◽

Content Type

Purpose The finite-time visual servoing control problem is considered for dynamic wheeled mobile robots (WMRs) with unknown control direction and external disturbance. Design/methodology/approach By using finite-time control method and switching design technique. Findings First, the visual servoing kinematic WMR model is developed, which can be converted to the dynamic chained-form systems by using a state and input feedback transformation. Then, for two decoupled subsystems of the chained-form systems, according to the finite-time stability control theory, a discontinuous three-step switching control strategy is proposed in the presence of uncertain control coefficients and external disturbance. Originality/value A class of discontinuous anti-interference control method has been presented for the dynamic nonholonomic systems.

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Composite Nonlinear Feedback for Vehicle Active Front Steering

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.663.127 ◽

2014 ◽

Vol 663 ◽

pp. 127-134 ◽

Cited By ~ 3

Author(s):

M.H. Che Hasan ◽

Y.M. Sam ◽

Ke Mao Peng ◽

Muhamad Khairi Aripin ◽

Muhamad Fahezal Ismail

Keyword(s):

Control Method ◽

Actuator Saturation ◽

External Disturbance ◽

Reference Signal ◽

Stability Control ◽

Nonlinear Feedback ◽

Composite Nonlinear Feedback ◽

Active Front Steering ◽

Yaw Stability ◽

Fast Settling

In this paper, Composite Nonlinear Feedback (CNF) is applied on Active Front Steering (AFS) system for vehicle yaw stability control in order to have an excellent transient response performance. The control method, which has linear and nonlinear parts that work concurrently capable to track reference signal very fast with minimum overshoot, fast settling time, and without exceed nature of actuator saturation limit. Beside, modelling of 7 degree of freedom for typical passenger car with magic formula to represent tyre nonlinearity behaviour is also presented to simulate controlled vehicle as close as possible with a real situation. An extensive computer simulation is performed with considering a various profile of cornering manoeuvres with external disturbance to evaluate its performance in different scenarios. The performance of the proposed controller is compared to conventional Proportional Integration and Derivative (PID) for effectiveness analysis.

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Stability control for end effect of mobile manipulator in uneven terrain based on active disturbance rejection control

Assembly Automation ◽

10.1108/aa-10-2020-0157 ◽

2021 ◽

Vol ahead-of-print (ahead-of-print) ◽

Author(s):

Chuang Cheng ◽

Hui Zhang ◽

Hui Peng ◽

Zhiqian Zhou ◽

Bailiang Chen ◽

...

Keyword(s):

Disturbance Rejection ◽

Control Method ◽

External Disturbance ◽

Stability Control ◽

Mobile Manipulator ◽

Active Disturbance Rejection Control ◽

End Effector ◽

Content Type ◽

Active Disturbance Rejection ◽

Disturbance Rejection Control

Purpose When the mobile manipulator is traveling on an unconstructed terrain, the external disturbance is generated. The load on the end of the mobile manipulator will be affected strictly by the disturbance. The purpose of this paper is to reject the disturbance and keep the end effector in a stable pose all the time, a control method is proposed for the onboard manipulator. Design/methodology/approach In this paper, the kinematics and dynamics models of the end pose stability control system for the tracked robot are built. Through the guidance of this model information, the control framework based on active disturbance rejection control (ADRC) is designed, which keeps the attitude of the end of the manipulator stable in the pitch, roll and yaw direction. Meanwhile, the control algorithm is operated with cloud computing because the research object, the rescue robot, aims to be lightweight and execute work with remote manipulation. Findings The challenging simulation experiments demonstrate that the methodology can achieve valid stability control performance in the challenging terrain road in terms of robustness and real-time. Originality/value This research facilitates the stable posture control of the end-effector of the mobile manipulator and maintains it in a suitable stable operating environment. The entire system can normally work even in dynamic disturbance scenarios and uncertain nonlinear modeling. Furthermore, an example is given to guide the parameter tuning of ADRC by using model information and estimate the unknown internal modeling uncertainty, which is difficult to be modeled or identified.

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Vehicle Lateral Motion Control Based on Estimated Stability Regions

Volume 1: Aerospace Applications; Advances in Control Design Methods; Bio Engineering Applications; Advances in Non-Linear Control; Adaptive and Intelligent Systems Control; Advances in Wind Energy Systems; Advances in Robotics; Assistive and Rehabilitation Robotics; Biomedical and Neural Systems Modeling, Diagnostics, and Control; Bio-Mechatronics and Physical Human Robot; Advanced Driver Assistance Systems and Autonomous Vehicles; Automotive Systems ◽

10.1115/dscc2017-5152 ◽

2017 ◽

Author(s):

Yiwen Huang ◽

Yan Chen

Keyword(s):

Measurement Errors ◽

Local Stability ◽

Stability Region ◽

Control Method ◽

Linearization Method ◽

Stability Control ◽

Lateral Stability ◽

Shortest Distance ◽

The Stability ◽

Yaw Moment

This paper presents a novel vehicle lateral stability control method based on an estimated lateral stability region on the phase plane of vehicle yaw rate and lateral speed, which is obtained through a local linearization method. Since the estimated stability region does not only describe vehicle local stability, but also define the oversteering and understeering characteristics, the proposed control method can achieve both local stability and vehicle handling stability. Considering the irregular geometric shape of the estimated stability region, a stability analysis algorithm is designed to determine the distance between vehicle states and stability region boundaries. State estimation or measurement errors are also incorporated in the distance calculation. Based on the calculated shortest distance between vehicle states and stability boundaries, a direct yaw moment controller is designed to maintain vehicle states stay within the stability region. CarSim® and Simulink® co-simulation is applied to verify the control design through a cornering maneuver. The simulation results show that the proposed control method can make the vehicle stay within the stability region successfully and thus always operate in a safe manner.

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Virtual DC Motor Stability Control Method Considering New Energy Generation Fluctuation

Journal of Physics Conference Series ◽

10.1088/1742-6596/2113/1/012015 ◽

2021 ◽

Vol 2113 (1) ◽

pp. 012015

Author(s):

Yilun Tan ◽

Yucheng Wang

Keyword(s):

Dynamic Response ◽

Control Method ◽

Rapid Development ◽

Regional Distribution ◽

Energy Generation ◽

Dc Motor ◽

Stability Control ◽

Transient Dynamic ◽

New Energy ◽

Transient Dynamic Response

Abstract With the rapid development of new energy generation, the intermittence and randomicity of its power output will have a significant impact on the transmission capacity of DC motor. Therefore, a virtual DC motor stability control method considering the fluctuation of new energy generation is proposed. The natural frequencies and modes of the virtual DC motor shafting rotor are analyzed by means of a steady sinusoidal excitation at zero speed. Considering the transient dynamic response of the shafting rotor of virtual DC motor under the fluctuation of new energy generation, Taylor series and transfer acceleration matrix method are used to calculate the transient dynamic response of shafting rotor under the fluctuation of new energy generation, and the parameters of virtual DC motor are identified and estimated. Based on this, a proportional resonance controller is designed to realize the stability control of virtual DC motor. Experimental results show that the interactive power curve between virtual DC motor and regional distribution network is smoother after optimal control, and this method can effectively improve the power balance ability of virtual DC motor.

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