Nowadays, controlling a Twin Rotor MIMO System (TRMS) is a considerable challenge for engineers due to its high non-linear attributes. The controller's design goals are to achieve the appropriate pitch and yaw angles when there is cross-coupling between its main and tail rotors while minimizing both the angular position error and controller effort. Performance measures can be utilized to evaluate the performance of the controller including integral square error, total variation, and integral absolute control action. In this paper, a Nonlinear Model Predictive Control (NMPC) is proposed to control TRMS rotors, which refer to the vertical and horizontal planes. Fick’s Law Algorithm (FLA) has been utilized to offline obtain the best selection for NMPC parameters. That includes best weighting matrices, shorter time steps, and shorter prediction horizons, by minimizing a novel penalty function called robust integral square error. FLA is used due to its flexibility, the ability to avoid suboptimal regions, and simplicity of implementation. The effectiveness of the proposed controller is examined using simulation-based tests conducted with MATLAB, which makes use of the CasADi Toolbox. In comparison to Cross Coupled PID (CC-PID) controller, the simulation results prove that FLA-based-NMPC has better performance and can track trajectories (step, square, and sine) even when there is ±30% in TRMS parameters perturbation. This work has come up with new contributions such as the new tuning strategy, extra state variable consideration, and a new FLA engineering application.

TRMS; Nonlinear Model Predictive Control (NMPC); Trajectory Tracking; Parameters Uncertainty; Robust Control; FLA; CasADi Toolbox; Cross Coupled PID.

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