Mathematical modeling and simulation of a half-vehicle suspension system in the roll plane-Reference-Cited by-同舟云学术

Mathematical modeling and simulation of a half-vehicle suspension system in the roll plane

Published:2024 Issue:1 Volume:72 Page:192-208
ISSN:0042-8469
Container-title:Vojnotehnicki glasnik
language:en
Short-container-title:Vojnotehnički glasnik

Author:

Benmeddah Abdeselem^ORCID,Drakulić Momir^ORCID,Đurić Aleksandar^ORCID,Perić Sreten^ORCID,Bukvić Aleksandar^ORCID,Ferfouri Abdellah^ORCID

Abstract

Introduction/purpose: The study of vehicle suspension is a challenge for researchers in the field of vehicles regarding the impact of the suspension system on vehicle performances such as ride comfort, road holding, and working space. This paper presents the simulation of the Land Rover Defender 110 vehicle in the roll plane (half vehicle) in Simulink/MATLAB. The obtained results were compared with the results obtained in the ADAMS/CAR software package of the Land Rover Defender 110 simulation model previously experimentally validated. The Defender 110 vehicle has a dependent suspension system in both axles and a passive suspension type with four degrees of freedom (4 DOF). Methods: The equations of the system can be solved mathematically with a scheme in Simulink/MATLAB while half-vehicle modeling has been done in ADAMS/CAR. Results: The comparison of the vehicle characteristics obtained by the two simulation methods was done for three different scenarios, and it was noticed that there is a good correlation between them. Conclusion: It was concluded that the Defender 110 vehicle simulation model in Simulink/MATLAB is validated. The validated model can be used to perform suspension system optimization in future work.

Publisher

Centre for Evaluation in Education and Science (CEON/CEES)

Link

https://scindeks-clanci.ceon.rs/data/pdf/0042-8469/2024/0042-84692401192B.pdf

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