Active control for actuator uncertain half-car suspension systems

2013 ◽  
pp. 125-142
Author(s):  
Hongyi Li ◽  
Honghai Liu
Keyword(s):  
Active Control ◽  
Suspension Systems ◽  
Car Suspension

On the statistical performance of active and semi-active car suspension systems

1989 ◽  
Vol 33 (3) ◽  
pp. 785-790 ◽  
Author(s):  
M.M. ElMadany ◽  
Z. Abduljabbar
Keyword(s):  
Suspension Systems ◽  
Car Suspension

Parameter Optimization and Active Control of Electromechanical Suspension Systems

2018 ◽  
pp. 265-276
Author(s):  
Willian Minnemann Kuhnert ◽  
Marcos Silveira ◽  
Paulo José Paupitz Gonçalves
Keyword(s):  
Active Control ◽  
Parameter Optimization ◽  
Suspension Systems

Adaptive Multiple-surface Sliding Control of Hydraulic Active Suspension Systems Based on the Function Approximation Technique

2005 ◽  
Vol 11 (5) ◽  
pp. 685-706 ◽  
Author(s):  
P. C. Chen ◽  
A. C. Huang
Keyword(s):  
Function Approximation ◽  
Ride Quality ◽  
Approximation Technique ◽  
Hydraulic Actuator ◽  
Tracking Errors ◽  
Suspension Systems ◽  
Car Suspension ◽  
Mismatched Uncertainties ◽  
Adaptive Laws ◽  
Function Approximation Technique

In this paper we propose an adaptive multiple-surface sliding controller (AMSSC) to control a non-autonomous quarter-car suspension system with hydraulic actuator. Due to the spring nonlinearities, the system property becomes asymmetric under the system’s own weight. Besides, because precise parameters of practical systems are hard to obtain, the system uncertainties should be dealt with. In this paper, these uncertainties are assumed to be lumped into three unknown functions such that the system model has both matched and mismatched uncertainties. Because the bounds of some of time-varying uncertainties are unavailable, traditional adaptive schemes or robust strategies are infeasible. To deal with this problem, a function approximation based adaptive multiple-surface sliding controller (AMSSC) is proposed in this paper. The multiple-surface sliding controller (MSSC) is used to cope with mismatched uncertainties while the function approximation technique is used to represent those uncertainties as finite combinations of basis functions. Adaptive laws for the approximating series can thus be derived based on the Lyapunov-like approach to ensure the closed-loop stability. Convergent performance of tracking errors can be obtained to improve the ride quality. Because the state measurements of the unsprung mass are lumped into the uncertainties, there is no need to feed back these signals with the proposed method. Therefore, the hardware structure can be simplified in the actual implementation. Computer simulations are performed to verify the effectiveness of the proposed strategy.

Performance Predictions for a Pneumatic Active Car Suspension System

1988 ◽  
Vol 202 (4) ◽  
pp. 243-250 ◽  
Author(s):  
R S Sharp ◽  
J H Hassan
Keyword(s):  
Active Control ◽  
Suspension System ◽  
Low Frequencies ◽  
Control Laws ◽  
Suspension Parameters ◽  
Car Suspension ◽  
Road Roughness ◽  
Performance Predictions ◽  
Set Up ◽  
Space Requirements

A mathematical model of a pneumatic active car suspension system in a single wheel station form excited by realistic road roughness input is set up. The active control is exerted through a d.c. motor-driven air-pump. The model is used to show that essentially all the advantages of active control, within the terms of reference, are obtained by employing the control only at low frequencies and having the suspension parameters adapt to the running conditions as they vary. Control laws are derived using limited state feedback, linear stochastic optimal control theory and power consumption, and space requirements are evaluated. System performance is shown to be good in comparison with other known arrangements and encouragement for further work to extend the results is given.

scholarly journals Active Control of Quarter Car Suspension System using Linear Quadratic Regulator

2011 ◽  
Vol 3 ◽  
pp. 364-372 ◽  
Author(s):  
M.P. Nagarkar ◽  
G.J. Vikhe ◽  
K.R. Borole ◽  
V.M. Nandedkar
Keyword(s):  
Active Control ◽  
Linear Quadratic Regulator ◽  
Suspension System ◽  
Linear Quadratic ◽  
Car Suspension ◽  
Quarter Car

Design and Control of a Power-Electronic Interface for Regenerative Suspension Systems

2019 ◽  
Author(s):  
Abdullah A. Algethami ◽  
Won-jong Kim
Keyword(s):  
Automobile Industry ◽  
Pulse Width Modulation ◽  
Damping Force ◽  
Control Effort ◽  
Suspension Systems ◽  
Car Suspension ◽  
Generator Voltage ◽  
And Control ◽  
Rectification Process ◽  
Electronic Interface

Abstract Recently, the automobile industry has begun applying an increasing number of systems to recycling wasted energy. One area that demands further research is the recycling and storing of energy in car suspension systems, especially in terms of developing an electronic interface to keep energy flowing bidirectionally. An electronic interface was designed to facilitate control of regenerative forces and store energy after the rectification process. The electronic interface was designed to be a symmetrical-bridgeless boost converter, due to this mechanism having few components and requiring little control effort. The converter was created such that it kept the current and voltage in phase for the maximum power factor. The input into this controller was the generator voltage used to determine the polarity of the pulse-width modulation, considering external road disturbances. Thus, this combination of converter and controller was able to replace an active controller. Variable resistance could be further controlled to manipulate the suspension damping force.

Energy Harvesting and Damping Capability of Quarter-Car Test Bed

2016 ◽  
Author(s):  
Abdullah A. Algethami ◽  
Won-jong Kim
Keyword(s):  
Energy Harvesting ◽  
Active Control ◽  
Suspension System ◽  
Test Bed ◽  
Efficient System ◽  
Car Suspension ◽  
Significant Interest ◽  
Quarter Car ◽  
Mass Spring ◽  
Damping Capability

Recovering and regenerating power in automotive applications has drawn significant interest recently. A car-suspension system can be modeled as a 2-DOF mass-spring-damper system. Active control used for the car suspension system produces results superior to other methods. In this study, a 3-phase linear generator is used to harvest energy and suppress vibration on a quarter-car suspension setup. The suspension system is analyzed to estimate the harvestable power and damping capability of the generator. Analysis for the generator and its efficiency are presented. Harvestable power of around 105 mW was achieved at a 3.5-Hz input disturbance. The regenerative suspension system can reduce the vibration of the sprung-mass acceleration by up to 22% in an indexed performance. Around 8.4 W used to drive the motor in active control was saved when the regenerative system was used. As a result, much energy can be saved by switching from the active to the energy-harvesting mode. A more efficient system can be designed by matching the mechanical and electromagnetic (EM) damping.

HALF CAR MAGNETORHEOLOGICAL SUSPENSION SYSTEM ACCOUNTING FOR NONLINEARITY AND TIME DELAY

2005 ◽  
Vol 19 (07n09) ◽  
pp. 1381-1387 ◽  
Author(s):  
X. M. DONG ◽  
MIAO YU ◽  
S. L. HUANG ◽  
ZUSHU LI ◽  
W. M. CHEN
Keyword(s):  
Time Delay ◽  
Ride Comfort ◽  
Linear Feedback ◽  
Linear Quadratic ◽  
Suspension Systems ◽  
Mr Dampers ◽  
Car Suspension ◽  
Magnetorheological Suspension ◽  
Suspension Model ◽  
Stability And Accuracy

MR suspension systems have significant non-linearity and time-delay characteristics. For this reason, linear feedback control of an MR suspension has limited vibration control performance. To address this problem, a four DOF half car suspension model with two MR dampers was adopted. Having analyzed non-linearity and time-delay of the MR suspension, a Human-Simulation Intelligent Control (HSIC) law with three levels was designed. Simulation verified effects of HSIC in solving the problem of non-linearity and time-delay of MR dampers. In comparison, simulation of linear-quadratic gaussian (LQG) without considering the non-linearity and time-delay of MR suspension is also made. The simulation results show that the HSIC controller is faster than LQG controller under bump input and has better stability and accuracy, and it can achieve smaller acceleration peak value and root mean square (RMS) and better ride comfort compared with LQG controller under random input.

The Optimal Control Method of Impulse Response in Prosthetic Leg

2014 ◽  
Vol 915-916 ◽  
pp. 1181-1185
Author(s):  
Xin Yi Xiao ◽  
Han Bin Xiao
Keyword(s):  
Optimal Control ◽  
Active Control ◽  
Impulse Response ◽  
Passive Control ◽  
Control Method ◽  
Control Variable ◽  
The Body ◽  
Control Techniques ◽  
Suspension Systems ◽  
Optimal Control Method

Passive control and semi-active control of vibration in mechanical systems have recently successfully been used in automobiles and airplanes suspension systems. These control techniques are able to guarantee the performances of all vibration structures. Unfortunately, the knowledge and data has not been readily applied to human prosthetics. The information collected can be directly applied to accelerate research into dampening for prosthetics. A focus of this paper is on modeling and controlling vibrations by a given impulse onto prosthetic legs. Simulations of using passive control and idealized skyhook dampening are using Matlab to complete. Through model analysis, control variable, simulation procedures and comparison of two modeling, the models have been refined and with idealized skyhook dampening suspension provide significant improvement of the body characteristics compared with passive suspensions.

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