%0 Journal Article %1 abdussalam_ali_ahmed_2021_4643513 %A Ahmed, Abdussalam Ali %D 2021 %J Global Journal of Engineering and Technology Advances %K Active Suspension %N 3 %P 088-097 %R 10.30574/gjeta.2021.6.3.0041 %T Quarter car model optimization of active suspension system using fuzzy PID and linear quadratic regulator controllers %U https://gjeta.com/content/quarter-car-model-optimization-active-suspension-system-using-fuzzy-pid-and-linear-quadratic %V 6 %X The primary objective of this paper is to improve the performance of a car's active suspension system and control the vibrations that occurred in the car's using two well-known control technologies, namely the Linear Quadratic Regulator (LQR) and fuzzy PID control. When the car suspension is designed, a quarter car model with two degrees of freedom is used. A complete control system is needed to provide the desired suspension performance and characteristics such as passenger comfort, road handling, and suspension deflection, this control system performed using the MATLAB/SIMULINK and includes three parts: input signals (actuator force and road profile), Controller part, and the suspension system model. The simulation results from the implemented Simulink models show a comparison between the uncontrolled suspension system and the suspension system with a fuzzy PID controller and the active suspension system of the car based on the linear-quadratic regulator, and it is explained thoroughly.

@article{abdussalam_ali_ahmed_2021_4643513, abstract = {The primary objective of this paper is to improve the performance of a car's active suspension system and control the vibrations that occurred in the car's using two well-known control technologies, namely the Linear Quadratic Regulator (LQR) and fuzzy PID control. When the car suspension is designed, a quarter car model with two degrees of freedom is used. A complete control system is needed to provide the desired suspension performance and characteristics such as passenger comfort, road handling, and suspension deflection, this control system performed using the MATLAB/SIMULINK and includes three parts: input signals (actuator force and road profile), Controller part, and the suspension system model. The simulation results from the implemented Simulink models show a comparison between the uncontrolled suspension system and the suspension system with a fuzzy PID controller and the active suspension system of the car based on the linear-quadratic regulator, and it is explained thoroughly.}, added-at = {2021-03-29T10:38:26.000+0200}, author = {Ahmed, Abdussalam Ali}, biburl = {https://www.bibsonomy.org/bibtex/26a0ab83598526bcac91dc3ed798a6b97/gjetajournal}, doi = {10.30574/gjeta.2021.6.3.0041}, interhash = {cc279be471e7cd0b683d18312d42e8eb}, intrahash = {6a0ab83598526bcac91dc3ed798a6b97}, issn = {2582-5003}, journal = {{Global Journal of Engineering and Technology Advances}}, keywords = {Active Suspension}, month = mar, number = 3, pages = {088-097}, timestamp = {2021-03-29T10:38:26.000+0200}, title = {Quarter car model optimization of active suspension system using fuzzy PID and linear quadratic regulator controllers}, url = {https://gjeta.com/content/quarter-car-model-optimization-active-suspension-system-using-fuzzy-pid-and-linear-quadratic}, volume = 6, year = 2021 }