论文信息 - Penalty Functions for Handling Large Deviation of Quadrature States in NMPC

Penalty Functions for Handling Large Deviation of Quadrature States in NMPC

Nonlinear Model Predictive Control for mechanical applications is often used to perform the tracking of time-varying reference trajectories, and is typically implemented using quadratic penalty functions. Controllers for mechanical systems, however, are often required to handle large deviations from the reference trajectory. In such cases, it has been observed that NMPC schemes based on quadratic penalties can have undesirably aggressive behaviours. Heuristics can be developed to tackle these issues, but they require intricate and non-systematic tuning procedures. This paper proposes an NMPC scheme based on a specific class of penalty functions to handle large deviations of quadrature states from their reference, offering an intuitive and easy-to-tune alternative. The behaviour of the proposed NMPC scheme is analysed, and the conditions for its nominal stability are established. The control scheme is illustrated on a simulated quadcopter.

Mario Zanon | Sebastien Gros | S. Gros | Mario Zanon

[1] Hans Bock,et al. An Efficient Algorithm for Nonlinear Model Predictive Control of Large-Scale Systems Part I: Description of the Method (Ein effizienter Algorithmus für die nichtlineare prädiktive Regelung großer Systeme Teil I: Methodenbeschreibung) , 2002 .

[2] Moritz Diehl,et al. Aircraft control based on fast non-linear MPC & multiple-shooting , 2012, 2012 IEEE 51st IEEE Conference on Decision and Control (CDC).

[3] James B. Rawlings,et al. Postface to “ Model Predictive Control : Theory and Design ” , 2012 .

[4] F. Allgöwer,et al. Nonlinear Model Predictive Control: From Theory to Application , 2004 .

[5] Stephen J. Wright,et al. Springer Series in Operations Research , 1999 .

[6] Moritz Diehl,et al. NMPC based on Huber penalty functions to handle large deviations of quadrature states , 2013, 2013 American Control Conference.

[7] David Schlipf,et al. Nonlinear model predictive control of wind turbines using LIDAR , 2013 .

[8] James B. Rawlings,et al. Optimizing Process Economic Performance Using Model Predictive Control , 2009 .

[9] H. Bock,et al. A Multiple Shooting Algorithm for Direct Solution of Optimal Control Problems , 1984 .

[10] Manfred Morari,et al. Efficient interior point methods for multistage problems arising in receding horizon control , 2012, 2012 IEEE 51st IEEE Conference on Decision and Control (CDC).