Litcius/Paper detail

Non-Convex Feedback Optimization with Input and Output Constraints

Verena Häberle, Adrian Hauswirth, Lukas Ortmann, Saverio Bolognani, Florian Dörfler

2020IEEE Control Systems Letters45 citationsDOIOpen Access PDF

Abstract

In this letter, we present a novel control scheme for feedback optimization. That is, we propose a discrete-time controller that can steer a physical plant to the solution of a constrained optimization problem without numerically solving the problem. Our controller can be interpreted as a discretization of a continuous-time projected gradient flow. Compared to other schemes used for feedback optimization, such as saddle-point schemes or inexact penalty methods, our control approach combines several desirable properties: it asymptotically enforces constraints on the plant steady-state outputs, and temporary constraint violations can be easily quantified. Our scheme requires only reduced model information in the form of steady-state input-output sensitivities of the plant. Further, global convergence is guaranteed even for non-convex problems. Finally, our controller is straightforward to tune, since the step-size is the only tuning parameter.

Topics & Concepts

DiscretizationConvergence (economics)Mathematical optimizationControl theory (sociology)Controller (irrigation)Convex optimizationSaddle pointRegular polygonOptimization problemConstraint (computer-aided design)Computer scienceSaddleMathematicsControl (management)BiologyEconomic growthEconomicsGeometryAgronomyArtificial intelligenceMathematical analysisAdvanced Control Systems OptimizationAdvanced Optimization Algorithms ResearchStability and Control of Uncertain Systems
Non-Convex Feedback Optimization with Input and Output Constraints | Litcius