核心概念
Harmonic Control Lyapunov Barrier Functions provide stability and safety guarantees for reach-avoid problems in control systems.
摘要
The paper introduces Harmonic Control Lyapunov Barrier Functions (harmonic CLBF) to address safety-critical systems and reach-avoid problems. It unifies harmonic functions with CLBFs to ensure stability and safety. The use of harmonic functions simplifies the imposition of CLBF constraints and allows for the derivation of optimal control strategies. The paper presents numerical results for different systems under various reach-avoid environments, demonstrating the effectiveness of harmonic CLBFs in reducing the risk of entering unsafe regions and increasing the probability of reaching the goal region.
Abstract
- Introduces harmonic CLBFs for constrained control problems.
- Exploits maximum principle for encoding CLBF properties.
- Control inputs maximize inner product with system dynamics.
Introduction
- Safety-critical systems modeled as constrained optimal control problems.
- Reach-avoid problems crucial for system stability and safety.
- Growing interest in reach-avoid problems in control theory.
Methodology
- Unifying harmonic functions with CLBFs for stability and safety.
- Deriving optimal controllers for reach-avoid tasks directly.
- Numerical experiments demonstrate low risk and high success rates.
Results
- Numerical results for Roomba, DiffDrive, and CarRobot systems.
- Comparison of deterministic and stochastic control policies.
- Effectiveness of harmonic CLBFs in ensuring safety and reaching goals.
Conclusion
- Harmonic CLBFs offer a novel approach to control theory.
- Unification of harmonic functions and CLBFs for stability and safety.
- Significant improvement in safety rates demonstrated through numerical experiments.
统计
Harmonic CLBFs show a significantly low risk of entering unsafe regions and a high probability of entering the goal region.
The control inputs are selected to maximize the inner product of the system dynamics with the steepest descent direction of the harmonic CLBF.
引用
"Harmonic CLBFs exploit the maximum principle to encode CLBF properties."
"Numerical results demonstrate improved safety rates with harmonic CLBFs."