Constrained linear quadratic regulation

The paper is a contribution to the theory of the infinite-horizon linear quadratic regulator (LQR) problem subject to inequality constraints on the inputs and states, extending an approach first proposed by Sznaier and Damborg (1987). A solution algorithm is presented, which requires solving a finite number of finite-dimensional positive definite quadratic programs. The constrained LQR outlined does not feature the undesirable mismatch between open-loop and closed-loop nominal system trajectories, which is present in the other popular forms of model predictive control (MPC) that can be implemented with a finite quadratic programming algorithm. The constrained LQR is shown to be both optimal and stabilizing. The solution algorithm is guaranteed to terminate in finite time with a computational cost that has a reasonable upper bound compared to the minimal cost for computing the optimal solution. Inherent to the approach is the removal of a tuning parameter, the control horizon, which is present in other MPC approaches and for which no reliable tuning guidelines are available. Two examples are presented that compare constrained LQR and two other popular forms of MPC. The examples demonstrate that constrained LQR achieves significantly better performance than the other forms of MPC on some plants, and the computational cost is not prohibitive for online implementation.

[1]  R. E. Kalman,et al.  Contributions to the Theory of Optimal Control , 1960 .

[2]  J. V. Vusse Plug-flow type reactor versus tank reactor , 1964 .

[3]  J. Richalet,et al.  Model predictive heuristic control: Applications to industrial processes , 1978, Autom..

[4]  C. R. Cutler,et al.  Dynamic matrix control¿A computer control algorithm , 1979 .

[5]  C. R. Cutler,et al.  Optimal Solution of Dynamic Matrix Control with Linear Programing Techniques (LDMC) , 1985, 1985 American Control Conference.

[6]  Mario Sznaier,et al.  Suboptimal control of linear systems with state and control inequality constraints , 1987, 26th IEEE Conference on Decision and Control.

[7]  E. Gilbert,et al.  Optimal infinite-horizon feedback laws for a general class of constrained discrete-time systems: Stability and moving-horizon approximations , 1988 .

[8]  D. Mayne,et al.  Robust receding horizon control of constrained nonlinear systems , 1993, IEEE Trans. Autom. Control..

[9]  J. Rawlings,et al.  The stability of constrained receding horizon control , 1993, IEEE Trans. Autom. Control..

[10]  James B. Rawlings,et al.  Nonlinear Model Predictive Control: A Tutorial and Survey , 1994 .

[11]  Kenneth Robert Muske,et al.  Linear model predictive control of chemical processes , 1995 .

[12]  James B. Rawlings,et al.  Implementable model predictive control in the state space , 1995, Proceedings of 1995 American Control Conference - ACC'95.

[13]  B. Bequette,et al.  Model predictive control of processes with input multiplicities , 1995 .

[14]  D. Chmielewski,et al.  On constrained infinite-time linear quadratic optimal control , 1996, Proceedings of 35th IEEE Conference on Decision and Control.

[15]  James B. Rawlings,et al.  Discrete-time stability with perturbations: application to model predictive control , 1997, Autom..

[16]  James B. Rawlings,et al.  Model Predictive Control , 2012 .