TR2026-005
Stability of relaxed barrier function based model predictive control with hard input
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- , "Relaxed barrier function based model predictive control with hard input constraints", IEEE Control Systems Letters, DOI: 10.1109/LCSYS.2025.3645287, Vol. 9, pp. 2927-2932, December 2025.BibTeX TR2026-005 PDF
- @article{Castroviejo-Fernandez2025dec,
- author = {Castroviejo-Fernandez, Miguel and Leung, Jordan},
- title = {{Relaxed barrier function based model predictive control with hard input constraints}},
- journal = {IEEE Control Systems Letters},
- year = 2025,
- volume = 9,
- pages = {2927--2932},
- month = dec,
- doi = {10.1109/LCSYS.2025.3645287},
- issn = {2475-1456},
- url = {https://www.merl.com/publications/TR2026-005}
- }
- , "Relaxed barrier function based model predictive control with hard input constraints", IEEE Control Systems Letters, DOI: 10.1109/LCSYS.2025.3645287, Vol. 9, pp. 2927-2932, December 2025.
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Abstract:
This letter focuses on a formulation of Model Predictive Control (MPC) with an optimal control problem (OCP) defined by hard input constraints and soft state and terminal set constraints. The soft constraints are accounted for as relaxed barrier function terms in the objective function. The proposed MPC is feasible for any state vector and, assuming the input constraint set is simple (e.g. a hyperrectangle), leads to anytime feasible formulations. A theoretical description of the MPC scheme is conducted. Among other results, asymptotic stability of the proposed MPC is proven and a region of attraction (RoA) estimate is derived. Moreover, stability guarantees when performing a limited number of optimization iterations are also derived. Numerical results showcase the benefit of considering the input constraints directly in the OCP instead of saturating the output of an unconstrained OCP with relaxed barrier functions, as was previously done in the literature.
Related News & Events
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NEWS MERL researchers present 8 papers at ACC 2026 Date: May 26, 2026 - May 29, 2026
Where: New Orleans, USA
MERL Contacts: Scott A. Bortoff; Vedang M. Deshpande; Stefano Di Cairano; Christopher R. Laughman; Jordan Leung; Hongtao Qiao; Zhaolin Ren; Abraham P. Vinod; Yebin Wang
Research Areas: Control, Dynamical Systems, Optimization, RoboticsBrief- MERL researchers presented 8 papers at the recently concluded American Control Conference (ACC) 2026 in New Orleans, USA. The papers covered a wide range of topics including robust controllable set computation, vapor compression cycle calibration, task-reasoning LLM agents, Minkowski-cost stable MPC, polynomial chaos approximation, invariant-set motion planning, heat-pump MPC architectures, and relaxed barrier-function MPC. Additionally, Zhaolin Ren was an invited speaker at Multi-Agent Dynamic Games workshop, and Abraham Vinod served as a panelist at the Professional Development and Career Advice for Young Professionals session.
As a sponsor of the conference, MERL maintained a booth for open discussions with researchers and students, and hosted a special session to discuss highlights of MERL research and work philosophy.
- MERL researchers presented 8 papers at the recently concluded American Control Conference (ACC) 2026 in New Orleans, USA. The papers covered a wide range of topics including robust controllable set computation, vapor compression cycle calibration, task-reasoning LLM agents, Minkowski-cost stable MPC, polynomial chaos approximation, invariant-set motion planning, heat-pump MPC architectures, and relaxed barrier-function MPC. Additionally, Zhaolin Ren was an invited speaker at Multi-Agent Dynamic Games workshop, and Abraham Vinod served as a panelist at the Professional Development and Career Advice for Young Professionals session.