Recursive Feasibility of Continuous-Time Model Predictive Control Without Stabilising Constraints
Willem Esterhuizen, Karl Worthmann, Stefan Streif
Abstract
We consider sampled-data Model Predictive Control (MPC) of nonlinear continuous-time control systems. We derive sufficient conditions to guarantee recursive feasibility and asymptotic stability without stabilising costs and/or constraints. Moreover, we present formulas to explicitly estimate the required length of the prediction horizon based on the concept of (local) cost controllability. For the linear-quadratic case, cost controllability can be inferred from standard assumptions. In addition, we extend results on the relationship between the horizon length and the distance of the initial state to the boundary of the viability kernel from the discrete-time to the continuous-time setting.
Topics & Concepts
Model predictive controlControllabilityControl theory (sociology)HorizonStability (learning theory)MathematicsMathematical optimizationNonlinear systemKernel (algebra)Time horizonBoundary (topology)Exponential stabilityState (computer science)Control (management)Nonlinear modelOptimal controlComputer scienceTerm (time)Applied mathematicsKernel density estimationSteady state (chemistry)Work (physics)Control systemEconomic modelMoving horizon estimationAdvanced Control Systems OptimizationControl Systems and IdentificationStability and Control of Uncertain Systems