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Autonomous Collision Avoidance Using MPC with LQR-Based Weight Transformation.

Shayan Taherian1, Kaushik Halder1, Shilp Dixit1

  • 1Department of Mechanical Engineering Sciences, Connected Autonomous Vehicle Lab (CAV-Lab), University of Surrey, Guildford GU2 7XH, UK.

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PubMed
Summary
This summary is machine-generated.

This study introduces an analytical method to tune Model Predictive Control (MPC) weights by matching Linear Quadratic Regulator (LQR) performance. This ensures optimal control and system stability, even with active constraints, as demonstrated in a vehicle collision avoidance system.

Keywords:
LQRLQTMPCcollision avoidanceinverse optimal controltrajectory planning

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Area of Science:

  • Control Systems Engineering
  • Robotics
  • Automotive Engineering

Background:

  • Model Predictive Control (MPC) is a powerful multi-objective control technique capable of managing system constraints.
  • The performance of MPC is highly sensitive to the accurate prioritization of weights for each objective, necessitating effective tuning methods.
  • Existing methods often struggle with precise weight tuning, impacting overall controller efficiency.

Purpose of the Study:

  • To develop an analytical weight tuning technique for Model Predictive Control (MPC).
  • To enhance MPC controller performance by aligning it with Linear Quadratic Regulator (LQR) controller benchmarks.
  • To ensure system stability and optimal performance under both unconstrained and constrained operational conditions.

Main Methods:

  • An analytical tuning technique is proposed by matching MPC performance with LQR controller performance.
  • The methodology involves deriving the transformation of an LQR weighting matrix using a discrete algebraic Riccati equation (DARE).
  • An MPC controller is designed based on the discrete-time linear quadratic tracking (LQT) problem, incorporating system constraints.

Main Results:

  • The proposed method achieves optimal performance between unconstrained MPC and LQR controllers.
  • It provides a sub-optimal solution when constraints are active during transient operations.
  • The resulting MPC controller ensures asymptotic stability and effectively mimics discrete-time LQR behavior with appropriate weighting matrix selection.

Conclusions:

  • The developed analytical tuning technique effectively optimizes MPC controller performance.
  • The method ensures system stability and optimal control, even under active constraints.
  • Validated through a vehicle collision avoidance system, the technique demonstrates potent collision-free path planning while respecting all system constraints.