Abstract
This paper combines the interval analysis tools with the nonlinear model predictive control (NMPC). The NMPC strategy is formulated based on an uncertain dynamic model expressed as nonlinear ordinary differential equations (ODEs). All the dynamic parameters are identified in a guaranteed way considering the various uncertainties on the embedded sensors and the system’s design. The NMPC problem is solved at each time step using validated simulation and interval analysis methods to compute the optimal and safe control inputs over a finite prediction horizon. This approach considers several constraints which are crucial for the system’s safety and stability, namely the state and the control limits. The proposed controller consists of two steps: filtering and branching procedures enabling to find the input intervals that fulfill the state constraints and ensure the convergence to the reference set. Then, the optimization procedure allows for computing the optimal and punctual control input that must be sent to the system’s actuators for the pendulum stabilization. The validated NMPC capabilities are illustrated through several simulations under the DynIbex library and experiments using an inverted pendulum.
Highlights
Despite their maturing technology, robotic solutions still face many challenges related mainly to their design and control techniques
Reliable H-infinity controllers for linear systems were designed in [3], in such a way that they ensure the asymptotic stability of the control systems, mainly when perturbations occur in some control components
Contributions : This paper focuses on developing a new validated and reliable nonlinear model predictive control (NMPC), which is designed using an uncertain mathematical model
Summary
Robotic solutions still face many challenges related mainly to their design and control techniques. Authors in [14] use IA methods to build a new nonlinear MPC law considering the discrete system It is based on forward-backward contraction using a dynamic model to compute feasible and admissible inputs. Contributions : This paper focuses on developing a new validated and reliable nonlinear model predictive control (NMPC), which is designed using an uncertain mathematical model. (ii) The second contribution lies in the synthesis of a validated NMPC strategy relying on the previous guaranteed identification to compute smooth and safe input intervals These approaches have been investigated through various simulations with uncertain high-order ordinary differential equations (ODEs) describing the system’s behavior. This device must be identified and stabilized in a validated and guaranteed way, considering all the errors and uncertainties related to the system modeling and data measurements
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