Lateral-acceleration-based vehicle-models-blending for automated driving controllers

Jose A. Matute-Peaspan, Mauricio Marcano, Sergio Diaz, Asier Zubizarreta, Joshue Perez

Research output: Contribution to journalArticlepeer-review

7 Citations (Scopus)

Abstract

Model-based trajectory tracking has become a widely used technique for automated driving system applications. A critical design decision is the proper selection of a vehicle model that achieves the best trade-off between real-time capability and robustness. Blending different types of vehicle models is a recent practice to increase the operating range of model-based trajectory tracking control applications. However, current approaches focus on the use of longitudinal speed as the blending parameter, with a formal procedure to tune and select its parameters still lacking. This work presents a novel approach based on lateral accelerations, along with a formal procedure and criteria to tune and select blending parameters, for its use on model-based predictive controllers for autonomous driving. An electric passenger bus traveling at different speeds over urban routes is proposed as a case study. Results demonstrate that the lateral acceleration, which is proportional to the lateral forces that differentiate kinematic and dynamic models, is a more appropriate model-switching enabler than the currently used longitudinal velocity. Moreover, the advanced procedure to define blending parameters is shown to be effective. Finally, a smooth blending method offers better tracking results versus sudden model switching ones and non-blending techniques.

Original languageEnglish
Article number1674
Pages (from-to)1-17
Number of pages17
JournalElectronics (Switzerland)
Volume9
Issue number10
DOIs
Publication statusPublished - 13 Oct 2020

Keywords

  • Automated driving
  • Model predictive control
  • Trajectory tracking
  • Vehicle control
  • Vehicle-model blending

Project and Funding Information

  • Project ID
  • info:eu-repo/grantAgreement/EC/H2020/737469/EU/Advancing fail-aware, fail-safe, and fail-operational electronic components, systems, and architectures for fully automated driving to make future mobility safer, affordable, and end-user acceptable/AUTODRIVE
  • Funding Info
  • This research was funded by AUTODRIVE within the Electronic Components and Systems for European Leadership Joint Undertaking (ECSEL JU) in collaboration with the European Union’s H2020 Framework Program (H2020/2014-2020) and National Authorities, under Grant No. 737469

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