GA-based multi-objective optimization of active nonlinear quarter car suspension system—PID and fuzzy logic control

Nagarkar, Mahesh; Bhalerao, Yogesh; Patil, G. J. Vikhe; Patil, Rahul N. Zaware

doi:10.1186/s40712-018-0096-8

Cited by 30 publications

(36 citation statements)

References 29 publications

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“…Meanwhile, in 1994, Srinivas and Deb [30] developed a new algorithm based on a GA called a nondominated sorting genetic algorithm (NSGA), and then in 2000, an improved version of the NSGA (called the NSGA-II) was developed by Deb et al [31]. With the merits of low computational complexities and the ability of parallel computation, it is widely used for MOPs [21,32]. Afterwards, in order to improve the distribution density of the Pareto front and avoid the problem of premature ripening, an improved NSGA-II was developed by introducing the parameter Pareto faction x, which represents the ratio of the optimal solutions to the total population (Equation (43)): where N represents the population size, and N Pareto represents the number of Pareto optimal solutions.…”

Section: Introduction Of Multiobjective Optimization Based On a Genetmentioning

confidence: 99%

Multiobjective Genetic Algorithm-Based Optimization of PID Controller Parameters for Fuel Cell Voltage and Fuel Utilization

et al. 2019

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Nowadays, given the great deal of fossil fuel consumption and associated environmental pollution, solid oxide fuel cells (SOFCs) have shown their great merits in terms of high energy conversion efficiency and low emissions as a stationary power source. To ensure power quality and efficiency, both the output voltage and fuel utilization of an SOFC should be tightly controlled. However, these two control objectives usually conflict with each other, making the controller design of an SOFC quite challenging and sophisticated. To this end, a multi-objective genetic algorithm (MOGA) was employed to tune the proportional–integral–derivative (PID) controller parameters through the following steps: (1) Identifying the SOFC system through a least squares method; (2) designing the control based on a relative gain array (RGA) analysis; and (3) applying the MOGA to a simulation to search for a set of optimal solutions. By comparing the control performance of the Pareto solutions, satisfactory control parameters were determined. The simulation results demonstrated that the proposed method could reduce the impact of disturbances and regulate output voltage and fuel utilization simultaneously (with strong robustness).

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Section: Introduction Of Multiobjective Optimization Based On a Genetmentioning

confidence: 99%

Multiobjective Genetic Algorithm-Based Optimization of PID Controller Parameters for Fuel Cell Voltage and Fuel Utilization

et al. 2019

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“…where n f is the number of nearby partners that is calculated by using the formula ‖AF j − AF i ‖ ≤ visual. e criteria for judging congestion are given by formula (10), which decides whether to follow formula (11).…”

Section: Afsa-based Optimization Methods and Procedurementioning

confidence: 99%

“…e experimental results from a quarter car test rig which were done by Mitra et al [9] show that mass and damping coefficient are the most influential parameters for ride comfort. erefore, many scholars focus their attention on optimizing the mass, damping coefficient, and stiffness coefficient of suspension system and achieve many significant results in enhancing ride comfort by using GA [10][11][12][13][14]. Essentially, the dynamics parameter optimization of suspension system belongs to a multiobjective optimization problem (MOOP) which can be solved by using multiobjective optimization algorithm (MOOA) [15,16].…”

Section: Introductionmentioning

confidence: 99%

Integrated Vibration Control of In‐Wheel Motor‐Suspensions Coupling System via Dynamics Parameter Optimization

Wang

Niu

Song

2019

Shock and Vibration

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In order to integrally control the vibration of in-wheel motor- (IWM-) suspensions coupling system of an electric vehicle, a novel nonlinear dynamics model of the coupling system, which consists of the motor magnetic gap (MMG), is established. Synthesizing subtargets of the vertical vibration acceleration of bodywork, the vertical deformation of tire, the suspension travel, and the vertical fluctuation of MMG, a composite optimization mathematical model is set up. Based on artificial fish swarm algorithm (AFSA), a novel dynamics parameter optimization method is proposed to search the optimal parameter combination existing in the nonlinear dynamics model. Simulation analyses demonstrate that the proposed optimization method is superior to genetic algorithm (GA) under the same optimization conditions, and it can significantly decrease the fluctuation of MMG and improve ride comfort.

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“…Narwade [11] studied the modelling and simulation of an automotive semi-active suspension system based on the PID controller, and conducted a simulation study for the application of the PID controller on automotive suspension in a more systematic way. Nagarkar [12] used PID and fuzzy control, based on a genetic algorithm, for an active non-linear 1/4 automotive suspension system to achieve multi-objective optimization of the suspension system. Although the above studies have achieved the optimization of suspension damping performance under passive suspension or classical PID control, it is still difficult to fundamentally solve the limitation of the PID controller control precision.…”

Section: Introductionmentioning

confidence: 99%

Fractional Order PID Control Based on Ball Screw Energy Regenerative Active Suspension

Zhang

Liu²,

Liu³

et al. 2022

Actuators

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A ball screw type energy regenerative active suspension under fractional order PID control is proposed and studied in order to improve the vibration damping performance of the suspension. A mathematical model of the energy regenerative actuator is established, the energy recovery power at different frequencies is measured through experiments, and then the electromagnetic torque constant, representing the proportional relationship between the output torque and current of the motor, is calculated according to the experimental results. A mathematical model of the control circuit is established and the feasibility and the superiority of the fractional order PID control are verified by simulation and experiments. To achieve a better damping effect, the fractional order PID controller of the whole vehicle suspension system is parameterized using the Beetle Antenna Search (BAS) algorithm. The results showed that the mean energy recovery power of the actuator was about 3.5091 W at a vibration frequency of 11/6 Hz, and the electromagnetic torque constant of the motor was about 0.2885. The actuator control circuit was feasible, and the root mean square value of current deviation under fractional order PID control was 1.1158 mA, which was optimized by 9.40%, compared to the PID control. The BAS algorithm effectively realized the parameter tuning of the controller, and both the tuned PID and fractional order PID controllers, achieved optimization of suspension damping performance. The optimal value of the damping performance objective function under fractional order PID control was 0.3270, which was optimized by 62.93%, compared to the PID control. In addition, all suspension performance indices under fractional order PID control were optimized to a certain extent, compared with the PID control.

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GA-based multi-objective optimization of active nonlinear quarter car suspension system—PID and fuzzy logic control

Cited by 30 publications

References 29 publications

Multiobjective Genetic Algorithm-Based Optimization of PID Controller Parameters for Fuel Cell Voltage and Fuel Utilization

Multiobjective Genetic Algorithm-Based Optimization of PID Controller Parameters for Fuel Cell Voltage and Fuel Utilization

Integrated Vibration Control of In‐Wheel Motor‐Suspensions Coupling System via Dynamics Parameter Optimization

Fractional Order PID Control Based on Ball Screw Energy Regenerative Active Suspension

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