Robust control barrier functions for constrained stabilization of nonlinear systems. Jankovic, M. Automatica, 96:359–367, October, 2018.
Robust control barrier functions for constrained stabilization of nonlinear systems [link]Paper  doi  abstract   bibtex   
Quadratic Programming (QP) has been used to combine Control Lyapunov and Control Barrier Functions (CLF and CBF) to design controllers for nonlinear systems with constraints. It has been successfully applied to robotic and automotive systems. The approach could be considered an extension of the CLF-based point-wise minimum norm controller. In this paper we modify the original QP problem in a way that guarantees that V˙ \textless 0, if the barrier constraint is inactive, as well as local asymptotic stability under the standard (minimal) assumptions on the CLF and CBF. We also remove the assumption that the CBF has uniform relative degree one. The two design parameters of the new QP setup allow us to control how aggressive the resulting control law is when trying to satisfy the two control objectives. The paper presents the controller in a closed form making it unnecessary to solve the QP problem on line and facilitating the analysis. Next, we introduce the concept of Robust-CBF that, when combined with existing ISS-CLFs, produces controllers for constrained nonlinear systems with disturbances. In an example, a nonlinear system is used to illustrate the ease with which the proposed design method handles nonconvex constraints and disturbances and to illuminate some tradeoffs.
@article{jankovic_robust_2018,
	title = {Robust control barrier functions for constrained stabilization of nonlinear systems},
	volume = {96},
	issn = {00051098},
	url = {https://linkinghub.elsevier.com/retrieve/pii/S0005109818303509},
	doi = {10.1016/j.automatica.2018.07.004},
	abstract = {Quadratic Programming (QP) has been used to combine Control Lyapunov and Control Barrier Functions (CLF and CBF) to design controllers for nonlinear systems with constraints. It has been successfully applied to robotic and automotive systems. The approach could be considered an extension of the CLF-based point-wise minimum norm controller. In this paper we modify the original QP problem in a way that guarantees that V˙ {\textless} 0, if the barrier constraint is inactive, as well as local asymptotic stability under the standard (minimal) assumptions on the CLF and CBF. We also remove the assumption that the CBF has uniform relative degree one. The two design parameters of the new QP setup allow us to control how aggressive the resulting control law is when trying to satisfy the two control objectives. The paper presents the controller in a closed form making it unnecessary to solve the QP problem on line and facilitating the analysis. Next, we introduce the concept of Robust-CBF that, when combined with existing ISS-CLFs, produces controllers for constrained nonlinear systems with disturbances. In an example, a nonlinear system is used to illustrate the ease with which the proposed design method handles nonconvex constraints and disturbances and to illuminate some tradeoffs.},
	language = {en},
	urldate = {2020-06-08},
	journal = {Automatica},
	author = {Jankovic, Mrdjan},
	month = oct,
	year = {2018},
	pages = {359--367},
}
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