Abstract
This paper presents a parameter estimation, robust controller design and performance analysis for an electric power steering (EPS) system. The parametrical analysis includes the EPS parameters and disturbances, such as the assist motor parameters, sensor-measurement noise, and random road factors, allowing the EPS stability to be extensively investigated. Based on the loop-shaping technique, the system controller is designed to increase the EPS stability and performance. The loop-shaping procedure is proposed to minimize the influence of system disturbances on the system outputs. The simplified refined instrumental variable (SRIV) algorithm, least squares state variable filter (LSSVF) algorithm and instrumental variable state variable filter (IVSVF) algorithm are applied to reduce the model mismatching between the theoretical EPS models and the real EPS model, as the EPS parameters can be accurately identified based on the experimental EPS data. The performance of the proposed method is thus compared to that of the proportional-integral-derivative (PID) test bench results for the EPS system. The experimental results demonstrated that the proposed loop-shaping controller provides good tracking performance while ensuring the stability of the EPS system.
Highlights
In grounded vehicles, the steering system plays an important role in ensuring the motion trajectory of the car according to the driver’s desires and road traffic
(electric power steering) systems have been widely deployed in modern vehicles due to their noticeable advantages over hydraulic power steering systems, including higher efficiency, more compact structure, better maintainability and lower fuel consumption [1,2,3,4,5]
In electric power steering (EPS) systems, the assist torque is generated by an electric motor, which is powered by the car battery
Summary
The steering system plays an important role in ensuring the motion trajectory of the car according to the driver’s desires and road traffic. In EPS systems, the assist torque is generated by an electric motor, which is powered by the car battery. The control strategies of assist torque need to consider the torque adjustment in accordance with the driver input torque, driver steering feeling and road conditions. PI-and PID-controlled EPS exhibited satisfactory performance, their performance can be further improved by considering model mismatching and disturbances, including friction and tire forces. To this end, EPS-based fuzzy controllers have been proposed to reduce the influence of friction and road disturbances [10,11]. It is essential to estimate the parameters of a plant based on both the input and output data.
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