Journal of Jilin University(Engineering and Technology Edition) ›› 2021, Vol. 51 ›› Issue (4): 1230-1240.doi: 10.13229/j.cnki.jdxbgxb20200642

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Linear disturbance observer suitable for sliding mode control of nonlinear active suspension

Jiang-qi LONG1(),Jin-tao XIANG1,Ping YU1(),Jun-cheng WANG2   

  1. 1.College of Mechanical and Electrical Engineering,Wenzhou University,Wenzhou 325000,China
    2.Faculty of Mechanical Engineering and Automation,Zhejiang Sci-Tech University,Hangzhou 310018,China
  • Received:2020-08-20 Online:2021-07-01 Published:2021-07-14
  • Contact: Ping YU E-mail:longjiangqi@163.com;yuping55@zju.edu.cn

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Abstract:

The active suspension based on the reference sky-hook model has problems such as nonlinear force, parameters uncertainty, and actuator non-ideality. To weaken the influence of these problems on the control effect, a linear disturbance observer (LDO) was proposed for estimating the uncertainties caused by the actuator imperfections, the nonlinear and uncertain parameters in the active suspension. Combined with sliding mode control (SMC) a control system is established. The influences of the sky-hook damping coefficient and uncertain parameters on the control effect are analyzed. After that, the method for selecting the sky-hook damping coefficient is proposed and the effectiveness of the observer is proved. Finally, the performance indexes of active suspension system with LDO-SMC based on reference skyhook model (LDO-SMCRSM) and SMC based on reference sky-hook model (SMCRSM) are calculated and compared in a bump and class-C road running condition. Simulation results shows that a better suspension performance can be obtained by using the proposed LDO-SMCRSM.

Key words: vehicle engineering, active suspension, linear disturbance observer, reference skyhook model, sliding mode control

CLC Number: 

  • U461.4

Fig.1

Nonlinear two-degree-of-freedom active suspension model"

Fig.2

Improved two-degree-of-freedom skyhook model"

Fig.3

Control principle diagram of control system with disturbance observer"

Table1

Basic parameters of active suspension system"

参数数值参数数值
ms/kg2.5k1.3
mus/kg1bn-3
ks1/(N?m-1)980bp2
ks2/(N?m-3)15 000cs2/(N?s2?m-2)100
cs1/(N?s?m-1)80kst/(N?m-1)2500
cst/(N?s?m-1)10zr/m0.035
ms0/kg2c12
ks0/(N?m-1)950k120
cs0/(N?s?m-1)80α600
k01μ00

Fig.4

Displacement changes of bump road"

Fig.5

Displacement changes of C-level road"

Fig.6

Structural simulation diagram of control system with observe"

Fig.7

Peak value of active suspension performance index in control system with disturbance observer"

Fig.8

Peak value of active suspension performance index in control system without disturbance observer"

Fig.9

Suspension performance index changes with spring mass"

Fig.10

Suspension performance indicators in the presence of dead zones"

Fig.11

Control principle diagram of control system without observe"

Fig.12

Structural simulation diagram of control system without observe"

Fig.13

Performance index of active suspension excited by bump model"

Fig.14

Active suspension performance index excited by class C road model"

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