Learning-Based Model Predictive Control for Autonomous Racing

Pinho, João Renato Rebello; Costa, Gabriel; Lima, Pedro U.; Botto, Miguel Ayala

doi:10.3390/wevj14070163

WEVJ

2023

DOI: 10.3390/wevj14070163

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Learning-Based Model Predictive Control for Autonomous Racing

João Renato Rebello Pinho

Gabriel Costa

Pedro U. Lima

et al.

Abstract: In this paper, we present the adaptation of the terminal component learning-based model predictive control (TC-LMPC) architecture for autonomous racing to the Formula Student Driverless (FSD) context. We test the TC-LMPC architecture, a reference-free controller that is able to learn from previous iterations by building an appropriate terminal safe set and terminal cost from collected trajectories and input sequences, in a vehicle simulator dedicated to the FSD competition. One major problem in autonomous raci… Show more

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2024

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Cited by 2 publications

References 32 publications

(59 reference statements)

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Integrated Motion Control Strategy Considering Parameter Robustness for Distributed Vehicle by Wire

Chen,

Bi,

Zhao

et al. 2024

SAE Int. J. Veh. Dyn., Stab., and NVH

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<div>To address the issues of functional conflicts in execution subsystems and the deterioration of control performance due to model parameter uncertainties in the motion control of distributed vehicle by wire, this article proposes an integrated control strategy considering parameter robustness. This strategy aims to compensate for model mismatch, resolve functional conflicts, and achieve motion coordination. Based on the over-actuation characteristics of distributed vehicle by wire, this article constructs the dynamic model and utilizes the tire cornering properties along with phase portraits to delineate the working regions of the execution subsystems. To deal with model parameter uncertainties and mismatch, tube-based model predictive control (tube-based MPC) is applied to the control strategy design, which compensates for model deviations through state feedback and constructs a robust positively invariant set (RPI) to constrain the system state. Correspondingly, the weights of control inputs are adjusted adaptively, according to the working regions, to optimize the coordination logic of integrated control. In order to verify the effectiveness and feasibility of the strategy, extreme driving condition tests are executed on hardware-in-the-loop (HIL) and real vehicle test platforms. The test results indicate that the strategy proposed in this article is able to reduce the sideslip angle and tracking error of yaw rate, improve driving stability under extreme conditions through integrated control, and especially, it can still maintain precise stability control performance under severe model mismatch, exhibiting strong robustness facing parameter uncertainties.</div>

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Learning-Based Model Predictive Control for Autonomous Racing

Cited by 2 publications

References 32 publications

How optimal is the minimum-time manoeuvre of an artificial race driver?

How optimal is the minimum-time manoeuvre of an artificial race driver?

Integrated Motion Control Strategy Considering Parameter Robustness for Distributed Vehicle by Wire

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