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A probabilistic quarter-car model for predicting worst-case vehicle performance

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dc.contributor.author Clarke, Anria
dc.contributor.author Sabatta, D
dc.date.accessioned 2018-10-26T09:47:37Z
dc.date.available 2018-10-26T09:47:37Z
dc.date.issued 2018-09
dc.identifier.citation Clarke, A. and Sabatta, D. 2018. A probabilistic quarter-car model for predicting worst-case vehicle performance. Eleventh South African Conference on Computational and Applied Mechanics (SACAM 2018), Vanderbijlpark, South Africa, 17-19 September 2018 en_US
dc.identifier.uri https://www.vut.ac.za/sacam2018/#1502791011790-fdff0ba6-6d10
dc.identifier.uri http://hdl.handle.net/10204/10505
dc.description Paper presented at the 11th South African Conference on Computational and Applied Mechanics (SACAM 2018), Vanderbijlpark, South Africa, 17-19 September 2018 en_US
dc.description.abstract Vehicle preview models have gained increasing popularity in recent years as a means of predicting potentially hazardous vehicle control inputs and attempting to mitigate their effects. These models are even more important in the field of autonomous vehicles as the vehicle itself is providing the potentially hazardous control input. In these cases, it is important to verify that these inputs will actually achieve the desired control objectives, and not result in a loss of traction or destabilisation of the vehicle. Unfortunately, the validity of these models is limited by the fidelity of the mathematical model and the accuracy of the estimated vehicle parameters. In the real-world, vehicle parameters are subject to change over time as a result of wear-and-tear, installation of after-market parts and vehicle loading. In this paper a method for propagating any uncertainty in the vehicle parameters through these models to determine variability in the output is presented. In doing so, worst-case estimates of the performance of the vehicle in certain situations may be provided. The authors introduce this method using the basic quarter-car model as a demonstrator. After developing the statistical model, the estimated outputs are verified using a Monte Carlo simulation, and conclusions are drawn on the performance of the vehicle under parameter uncertainty. The results show that under ideal road conditions, any parameter uncertainty has very little effect on the road-holding performance of a vehicle, but on increasingly rougher roads, this parameter uncertainty plays a substantially larger role. As such, the methods presented in this paper are therefore suitable for use in self-driving cars that are designed to operate in off-road conditions. en_US
dc.language.iso en en_US
dc.relation.ispartofseries Worklist;21581
dc.subject Quarter-car model en_US
dc.subject Stochastic mechanics en_US
dc.subject Autonomous vehicle en_US
dc.subject Dynamic load coefficient en_US
dc.title A probabilistic quarter-car model for predicting worst-case vehicle performance en_US
dc.type Conference Presentation en_US
dc.identifier.apacitation Clarke, A., & Sabatta, D. (2018). A probabilistic quarter-car model for predicting worst-case vehicle performance. http://hdl.handle.net/10204/10505 en_ZA
dc.identifier.chicagocitation Clarke, Anria, and D Sabatta. "A probabilistic quarter-car model for predicting worst-case vehicle performance." (2018): http://hdl.handle.net/10204/10505 en_ZA
dc.identifier.vancouvercitation Clarke A, Sabatta D, A probabilistic quarter-car model for predicting worst-case vehicle performance; 2018. http://hdl.handle.net/10204/10505 . en_ZA
dc.identifier.ris TY - Conference Presentation AU - Clarke, Anria AU - Sabatta, D AB - Vehicle preview models have gained increasing popularity in recent years as a means of predicting potentially hazardous vehicle control inputs and attempting to mitigate their effects. These models are even more important in the field of autonomous vehicles as the vehicle itself is providing the potentially hazardous control input. In these cases, it is important to verify that these inputs will actually achieve the desired control objectives, and not result in a loss of traction or destabilisation of the vehicle. Unfortunately, the validity of these models is limited by the fidelity of the mathematical model and the accuracy of the estimated vehicle parameters. In the real-world, vehicle parameters are subject to change over time as a result of wear-and-tear, installation of after-market parts and vehicle loading. In this paper a method for propagating any uncertainty in the vehicle parameters through these models to determine variability in the output is presented. In doing so, worst-case estimates of the performance of the vehicle in certain situations may be provided. The authors introduce this method using the basic quarter-car model as a demonstrator. After developing the statistical model, the estimated outputs are verified using a Monte Carlo simulation, and conclusions are drawn on the performance of the vehicle under parameter uncertainty. The results show that under ideal road conditions, any parameter uncertainty has very little effect on the road-holding performance of a vehicle, but on increasingly rougher roads, this parameter uncertainty plays a substantially larger role. As such, the methods presented in this paper are therefore suitable for use in self-driving cars that are designed to operate in off-road conditions. DA - 2018-09 DB - ResearchSpace DP - CSIR KW - Quarter-car model KW - Stochastic mechanics KW - Autonomous vehicle KW - Dynamic load coefficient LK - https://researchspace.csir.co.za PY - 2018 T1 - A probabilistic quarter-car model for predicting worst-case vehicle performance TI - A probabilistic quarter-car model for predicting worst-case vehicle performance UR - http://hdl.handle.net/10204/10505 ER - en_ZA


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