Real-time Damper Force Estimation for Automotive Suspension

Q2 Engineering

Periodica Polytechnica Transportation Engineering Pub Date : 2022-08-02 DOI:10.3311/pptr.20076

Thanh-Phong Pham, Gia Quoc Bao Tran, O. Sename, Thi Thanh Van Phan, Dung Hoang, Quoc Dinh Nguyen

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引用次数: 0

Abstract

The real-time knowledge of the damper force is of paramount importance in controlling and diagnosing automotive suspension systems. This study presents a generalized H2/LPV observer for damper force estimation of a semi-active electro-rheological (ER) suspension system. First, an extended quarter-car model augmented with the nonlinear and dynamical model of the semi-active suspension system is written into the quasi-LPV formulation. Then, the damper force estimation method is developed through a generalized H2/LPV observer whose objective is to handle the impact of unknown road disturbances and sensor noise on the estimation errors of the state variables thanks to the H2 norm. The measured sprung and unsprung mass accelerations of the quarter-car system are used as inputs for the observer. The proposed approach is simulated with validated model of the 1/5-scaled real vehicle testbed of GIPSA-lab. Simulation results show the performance of the estimation method against unknown disturbances, emphasizing the effectiveness of the damper force estimation in real time.

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汽车悬架减振器力的实时估计

阻尼力的实时信息对汽车悬架系统的控制和诊断至关重要。提出了一种用于半主动电流变(ER)悬架系统阻尼力估计的广义H2/LPV观测器。首先，将半主动悬架系统的非线性动力学模型扩充为扩展的四分之一小车模型，并将其写入拟lpv公式。然后，通过广义H2/LPV观测器开发了阻尼器力估计方法，该观测器的目的是处理未知道路干扰和传感器噪声对H2范数对状态变量估计误差的影响。测得的四分之一小车系统的簧载和非簧载质量加速度作为观测器的输入。该方法在GIPSA-lab 1/5比例实车试验台的验证模型上进行了仿真。仿真结果表明了该方法对未知干扰的估计性能，强调了阻尼力实时估计的有效性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Periodica Polytechnica Transportation Engineering Engineering-Automotive Engineering

CiteScore

2.60

自引率

0.00%

发文量

期刊介绍： Periodica Polytechnica is a publisher of the Budapest University of Technology and Economics. It publishes seven international journals (Architecture, Chemical Engineering, Civil Engineering, Electrical Engineering, Mechanical Engineering, Social and Management Sciences, Transportation Engineering). The journals have free electronic versions.