Ride Comfort Enhancement of MR-Damped Vehicle Suspension System Based on Fractional Order Fuzzy PI+D Controller

Abstract In this paper, a fractional order fuzzy proportional-integral plus differential (FOFPI+D) controller is presented for nonlinear vehicle semi-active suspension system (SAS). The control goal is to meliorate the ride quality level by minimizing the root mean square of vehicle body vertical acceleration (RMSVBVA) and maintaining suspension travel. The FOFPI+D controller is realized using non-integer differentiator operator in fuzzy proportional integral (FPI) controller plus the derivative (D) action with additional fractional differentiator. A dynamical model of four degrees–of–freedom vehicle suspension system incorporating magnetorheological dampers (MRD’s) is derived and simulated using Matlab/Simulink software. The performance of the semi-active suspension system using FOFPI+D controller is compared to MR-passive suspension system. The simulation results prove that semi-active suspension system controlled using FOFPI+D outperform and offer better comfort ride under road profiles such as random and bump.

Optimized Fractional-Order Proportional Integral Derivative Controller for Active Vehicle Suspension System Performance Enhancement

International Journal of Vehicle Structures and Systems ◽

10.4273/ijvss.10.4.15 ◽

2018 ◽

Vol 10 (4) ◽

Author(s):

A.S. Emam ◽

H. Metered ◽

A.M. Abdel Ghany

Keyword(s):

Fractional Order ◽

Performance Enhancement ◽

Ride Comfort ◽

Active Suspension ◽

Suspension System ◽

Vehicle Suspension ◽

Vehicle Stability ◽

Proportional Integral Derivative ◽

Proportional Integral ◽

In this paper, an optimal Fractional Order Proportional Integral Derivative (FOPID) controller is applied in vehicle active suspension system to improve the ride comfort and vehicle stability without consideration of the actuator. The optimal values of the five gains of FOPID controller to minimize the objective function are tuned using a Multi-Objective Genetic Algorithm (MOGA). A half vehicle suspension system is modelled mathematically as 6 degrees-of-freedom mechanical system and then simulated using Matlab/Simulink software. The performance of the active suspension with FOPID controller is compared with passive suspension system under bump road excitation to show the efficiency of the proposed controller. The simulation results show that the active suspension system using the FOPID controller can offer a significant enhancement of ride comfort and vehicle stability.

Performance Comparison of Various controllers on Semi-Active Vehicle Suspension System

ITM Web of Conferences ◽

10.1051/itmconf/20214001001 ◽

2021 ◽

Vol 40 ◽

pp. 01001

Author(s):

Sarvesh Walavalkar ◽

Viraj Tandel ◽

Rahul Sunil Thakur ◽

V.V Pramod Kumar ◽

Supriya Bhuran

Keyword(s):

Active Suspension ◽

Suspension System ◽

Internal Model Control ◽

Vehicle Body ◽

Vehicle Suspension ◽

Inference System ◽

Proportional Integral ◽

Suspension Systems ◽

Model Control ◽

The value of a self-tuning adaptive semi-active control scheme for automotive suspension systems is discussed in this paper. The current vehicle suspension system uses fixed-coeffcient springs and dampers. The ability of vehicle suspension systems to provide good road handling and improve passenger comfort is usually valued. Passive suspension allows you to choose between these two options. Semi-Active suspension(SAS), on the other hand, can provide both road handling and comfort by manipulating the suspension force actuators directly. The semi-active suspension system for a quarter car model is compared to passive and various controllers such as Proportional-Integral, Proportional-Integral-Derivative, Internal model control (IMC)-PID, IMC-PID with filter, FUZZY, and Adaptive-network-based fuzzy inference system(ANFIS) in this analysis. This research could be relevant in the future for designing better car suspension adjustments to eliminate vertical jerks and rolling motion experienced by the vehicle body on bumps and humps.

Optimal control and parameters design for the fractional-order vehicle suspension system

Journal of Low Frequency Noise Vibration and Active Control ◽

10.1177/0263092317717166 ◽

2018 ◽

Vol 37 (3) ◽

pp. 456-467 ◽

Cited By ~ 7

Author(s):

Hao You ◽

Yongjun Shen ◽

Haijun Xing ◽

Shaopu Yang

Keyword(s):

Optimal Control ◽

Fractional Order ◽

Suspension System ◽

Least Square ◽

Vehicle Body ◽

Vehicle Suspension ◽

Vertical Acceleration ◽

Control Force ◽

Suspension Systems ◽

In this paper the optimal control and parameters design of fractional-order vehicle suspension system are researched, where the system is described by fractional-order differential equation. The linear quadratic optimal state regulator is designed based on optimal control theory, which is applied to get the optimal control force of the active fractional-order suspension system. A stiffness-damping system is added to the passive fractional-order suspension system. Based on the criteria, i.e. the force arising from the accessional stiffness-damping system should be as close as possible to the optimal control force of the active fractional-order suspension system, the parameters of the optimized passive fractional-order suspension system are obtained by least square algorithm. An Oustaloup filter algorithm is adopted to simulate the fractional-order derivatives. Then, the simulation models of the three kinds of fractional-order suspension systems are developed respectively. The simulation results indicate that the active and optimized passive fractional-order suspension systems both reduce the value of vehicle body vertical acceleration and improve the ride comfort compared with the passive fractional-order suspension system, whenever the vehicle is running on a sinusoidal surface or random surface.

Research on vibration reduction of semi-active suspension system of quarter vehicle based on time-delayed feedback control with body acceleration

Journal of Low Frequency Noise Vibration and Active Control ◽

10.1177/14613484211051845 ◽

2021 ◽

pp. 146134842110518

Author(s):

Yong Guo ◽

Chuanbo Ren

Keyword(s):

Feedback Control ◽

Delayed Feedback ◽

Suspension System ◽

Delayed Feedback Control ◽

Vehicle Body ◽

Vehicle Suspension ◽

Vertical Acceleration ◽

Control Parameters ◽

Time Delayed Feedback

In this paper, the mechanical model of two-degree-of-freedom vehicle semi-active suspension system based on time-delayed feedback control with vertical acceleration of the vehicle body was studied. With frequency-domain analysis method, the optimization of time-delayed feedback control parameters of vehicle suspension system in effective frequency band was studied, and a set of optimization method of time-delayed feedback control parameters based on “equivalent harmonic excitation” was proposed. The time-domain simulation results of vehicle suspension system show that compared with the passive control, the time-delayed feedback control based on the vertical acceleration of the vehicle body under the optimal time-delayed feedback control effectively broadens the vibration absorption bandwidth of the vehicle suspension system. The ride comfort and stability of the vehicle under random road excitation are significantly improved, which provides a theoretical basis for the selection of time-delayed feedback control strategy and the optimal design of time-delayed feedback control parameters of vehicle suspension system.

Design of LQG Controller for Active Suspension without Considering Road Input Signals

Shock and Vibration ◽

10.1155/2017/6573567 ◽

2017 ◽

Vol 2017 ◽

pp. 1-13 ◽

Cited By ~ 3

Author(s):

Hui Pang ◽

Ying Chen ◽

JiaNan Chen ◽

Xue Liu

Keyword(s):

Angular Acceleration ◽

Active Suspension ◽

Suspension System ◽

Vehicle Body ◽

Vehicle Suspension ◽

Linear Quadratic ◽

The Road ◽

Input Signals ◽

Weight Coefficients

As the road conditions are completely unknown in the design of a suspension controller, an improved linear quadratic and Gaussian distributed (LQG) controller is proposed for active suspension system without considering road input signals. The main purpose is to optimize the vehicle body acceleration, pitching angular acceleration, displacement of suspension system, and tire dynamic deflection comprehensively. Meanwhile, it will extend the applicability of the LQG controller. Firstly, the half-vehicle and road input mathematical models of an active suspension system are established, with the weight coefficients of each evaluating indicator optimized by using genetic algorithm (GA). Then, a simulation model is built in Matlab/Simulink environment. Finally, a comparison of simulation is conducted to illustrate that the proposed LQG controller can obtain the better comprehensive performance of vehicle suspension system and improve riding comfort and handling safety compared to the conventional one.

A Pneumatic Artificial Muscle Bionic Kangaroo Leg Suspension

Recent Patents on Mechanical Engineering ◽

10.2174/2212797612666190808100422 ◽

2019 ◽

Vol 12 (4) ◽

pp. 357-366

Author(s):

Yong Song ◽

Shichuang Liu ◽

Jiangxuan Che ◽

Jinyi Lian ◽

Zhanlong Li ◽

...

Keyword(s):

Strong Shock ◽

Artificial Muscle ◽

Suspension System ◽

Vehicle Body ◽

Vehicle Suspension ◽

Pneumatic Artificial Muscle ◽

Advantages And Disadvantages ◽

Road Excitation ◽

Suspension Structure

Background: Vehicles generally travel on different road conditions, and withstand strong shock and vibration. In order to reduce or isolate the strong shock and vibration, it is necessary to propose and develop a high-performance vehicle suspension system. Objective: This study aims to report a pneumatic artificial muscle bionic kangaroo leg suspension to improve the comfort performance of vehicle suspension system. Methods: In summarizing the existing vehicle suspension systems and analyzing their advantages and disadvantages, this paper introduces a new patent of vehicle suspension system based on the excellent damping and buffering performance of kangaroo leg, A Pneumatic Artificial Muscle Bionic Kangaroo Leg Suspension. According to the biomimetic principle, the pneumatic artificial muscles bionic kangaroo leg suspension with equal bone ratio is constructed on the basis of the kangaroo leg crural index, and two working modes (passive and active modes) are designed for the suspension. Moreover, the working principle of the suspension system is introduced, and the rod system equations for the suspension structure are built up. The characteristic simulation model of this bionic suspension is established in Adams, and the vertical performance is analysed. Results: It is found that the largest deformation happens in the bionic heel spring and the largest angle change occurs in the bionic ankle joint under impulse road excitation, which is similar to the dynamic characteristics of kangaroo leg. Furthermore, the dynamic displacement and the acceleration of the vehicle body are both sharply reduced. Conclusion: The simulation results show that the comfort performance of this bionic suspension is excellent under the impulse road excitation, which indicates the bionic suspension structure is feasible and reasonable to be applied to vehicle suspensions.

Feedback control for two-degree-of-freedom vibration system with fractional-order derivative damping

Journal of Low Frequency Noise Vibration and Active Control ◽

10.1177/1461348417725958 ◽

2017 ◽

Vol 37 (3) ◽

pp. 554-564

Author(s):

Canchang Liu ◽

Chicheng Ma ◽

Jilei Zhou ◽

Lu Liu ◽

Shuchang Yue ◽

...

Keyword(s):

Feedback Control ◽

Nonlinear Vibration ◽

Fractional Order ◽

Suspension System ◽

Degree Of Freedom ◽

Vehicle Suspension ◽

Vibration System ◽

Fractional Order Derivative ◽

Two Degree Of Freedom

A two-degree-of-freedom nonlinear vibration system of a quarter vehicle suspension system is studied by using the feedback control method considered the fractional-order derivative damping. The nonlinear dynamic model of two-degree-of-freedom vehicle suspension system is built and linear velocity and displacement controllers are used to control the nonlinear vibration of the vehicle suspension system. A case of the 1:1 internal resonance is considered. The amplitude–frequency response is obtained with the multiscale method. The asymptotic stability conditions of the nonlinear system can be gotten by using the Routh–Hurwitz criterion and the ranges of control parameters are gained in the condition of stable solutions to the system. The simulation results show that the feedback control can effectively reduce the amplitude of primary resonance, weaken or even eliminate the nonlinear vibration characteristics of the suspension system. Fractional orders have an impact on control performance, which should be considered in the control problem. The study will provide a theoretical basis and reference for the optimal design of the vehicle suspension system.

Two-Dimensional Dynamics of Tracked Ram Air Cushion Vehicles With Fixed and Variable Winglets

Journal of Dynamic Systems Measurement and Control ◽

10.1115/1.3426446 ◽

1979 ◽

Vol 101 (4) ◽

pp. 321-331

Author(s):

L. M. Sweet ◽

H. C. Curtiss ◽

R. A. Luhrs

Keyword(s):

Active Suspension ◽

Suspension System ◽

Ride Quality ◽

Vertical Acceleration ◽

Suspension Systems ◽

Active Suspension Systems ◽

Air Cushion ◽

Linearized Model ◽

The One ◽

Air Cushion Vehicles

A linearized model of the pitch-heave dynamics of a Tracked Ram Air Cushion Vehicle is presented. This model is based on aerodynamic theory which has been verified by wind tunnel and towed model experiments. The vehicle is assumed to be equipped with two controls which can be configured to provide various suspension system characteristics. The ride quality and dynamic motions of the fixed winglet vehicle moving at 330 km/hr over a guideway described by roughness characteristics typical of highways is examined in terms of the rms values of the vertical acceleration in the foremost and rearmost seats in the passenger cabin and the gap variations at the leading and trailing edges of the vehicle. The improvement in ride quality and dynamic behavior which can be obtained by passive and active suspension systems is examined and discussed. Optimal regulator theory is employed to design the active suspension system. The predicted rms values of the vertical acceleration in the one-third octave frequency bands are compared with the vertical ISO Specifications. It is shown that marked improvements in the ride quality can be obtained with either the passive or active suspension systems.

An Approach on Performance Comparison of Quarter Car Suspension System

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.984-985.629 ◽

2014 ◽

Vol 984-985 ◽

pp. 629-633

Author(s):

Palanisamy Sathishkumar ◽

Jeyaraj Jancirani ◽

John Dennie

Keyword(s):

Degrees Of Freedom ◽

Performance Comparison ◽

Suspension System ◽

Vehicle Body ◽

Vehicle Suspension ◽

Passive Suspension ◽

Passenger Comfort ◽

Car Model ◽

Car Suspension ◽

The present article introduces an approach that combines passive and active elements to improve the ride and passenger comfort. The main aim of vehicle suspension system should isolate the vehicle body from road unevenness for maintaining ride and passenger comfort. The ride and passenger comfort is improved by reducing the car body acceleration caused by the irregular road surface. The vehicle body along with the wheel system is modelled as two degrees of freedom one fourth of car model. The model is tested on road bump with severe peak amplitude excitations. In the conclusion, a comparison of active, semi-active and passive suspension is shown using MATLAB simulations.

Enhancement of the Vehicle Suspension Performance Using Motion-Doubling Linkage Mechanisms

Volume 2: 30th Annual Mechanisms and Robotics Conference, Parts A and B ◽

10.1115/detc2006-99504 ◽

2006 ◽

Author(s):

Jahangir Rastegar ◽

Kavous Jorabchi ◽

Hee J. Park

Keyword(s):

Suspension System ◽

Vehicle Suspension ◽

Vertical Acceleration ◽

Linkage Mechanism ◽

New Class ◽

Suspension Systems ◽

Full Rotation ◽

Rocking Motion ◽

Suspension Performance

In recent studies, a new class of planar and spatial linkage mechanisms was presented in which for a continuous full rotation or continuous rocking motion of the input link, the output link undergoes two continuous rocking motions. Such linkage mechanisms were referred to as the “motion-doubling” linkage mechanisms. This class of mechanisms was also shown to generally have dynamics advantage over regular mechanisms designed to achieve similar gross output motions. In the present study, the use of the motion-doubling linkage mechanisms in the construction of vehicle suspension systems is investigated. The performance of the resulting vehicle suspension system is compared to that of a suspension system regularly used in vehicles. For a typical set of vehicle and tire parameters, the parameters of both suspension systems are optimally determined with a commonly used objective function, which is defined as the standard deviation of the vertical acceleration of the vehicle. Using numerical simulation, it is shown that the suspension system constructed with a motion-doubling linkage mechanism has a significantly better performance as compared to a standard suspension system.