Hybrid model predictive control application towards optimal semi-active suspension

The optimal control problem of a quarter-car semi-active suspension has been studied in the past. Considering that a quarter-car semi-active suspension can either be modelled as a linear system with state dependent constraint on control (of actuator force) input, or a bi-linear system with a control (of variable damping coefficient) saturation, the seemingly simple problem poses several interesting questions and challenges. Does the saturated version of the optimal control law derived from the corresponding un-constrained system, i.e. “clipped-optimal”, remain optimal for the constrained case as suggested in some previous publications? Or should the optimal deviate from the “clipped-optimal” as suggested in other publications? If the optimal control law of the constrained system does deviate from its unconstrained counter-part, how different are they? What is the structure of the optimal control law? Does it retain the linear state feedback form (as the unconstrained case)? In this paper, we attempt to answer some of the above questions by utilizing the recent development in model predictive control (MPC) of hybrid dynamical systems. The constrained quarter-car semi-active suspension is modelled as a switching affine system, where the switching is determined by the activation of passivity constraints, force saturation, and maximum power dissipation limits. Theoretically, over an infinite prediction horizon the MPC controller corresponds to the exact optimal controller. The performance of different finite-horizon hybrid MPC controllers is tested in simulation using mixed-integer quadratic programming. Then, for short-horizon MPC controllers, we derive the explicit optimal control law and show that the optimal control is piecewise affine in state. In the process, we show that for horizon equal to one the explicit MPC control law corresponds to clipped LQR as expected. We also compare the derived optimal control law to various semi-active control laws in the literature including the well-known “clipped-optimal”. We evaluate their corresponding performances for both a deterministic shock input case and a stochastic random disturbances case through simulations.

[1]  Donald Margolis,et al.  Realistic Road-Track Systems Simulation Using Digital Computers , 1975 .

[2]  Donald L. Margolls THE RESPONSE OF ACTIVE AND SEMI-ACTIVE SUSPENSIONS TO REALISTIC FEEDBACK SIGNALS , 1982 .

[3]  Dean Karnopp,et al.  ACTIVE DAMPING IN ROAD VEHICLE SUSPENSION SYSTEMS , 1983 .

[4]  Donald Margolis Semi-Active Control of Wheel Hop in Ground Vehicles , 1983 .

[5]  Davor Hrovat,et al.  An approach toward the optimal semi-active suspension , 1988 .

[6]  H. E. Tseng,et al.  Semi-Active Control Laws - Optimal and Sub-Optimal , 1994 .

[7]  Karen Rudie,et al.  A survey of modeling and control of hybrid systems , 1997 .

[8]  D. Hrovat,et al.  Survey of Advanced Suspension Developments and Related Optimal Control Applications, , 1997, Autom..

[9]  Alberto Bemporad,et al.  Control of systems integrating logic, dynamics, and constraints , 1999, Autom..

[10]  Panos J. Antsaklis,et al.  Special issue on hybrid systems: theory and applications a brief introduction to the theory and applications of hybrid systems , 2000, Proc. IEEE.

[11]  Alberto Bemporad,et al.  A Hybrid Approach to Traction Control , 2001, HSCC.

[12]  Bart De Schutter,et al.  Equivalence of hybrid dynamical models , 2001, Autom..

[13]  Alberto Bemporad,et al.  A hybrid system approach to modeling and optimal control of DISC engines , 2002, Proceedings of the 41st IEEE Conference on Decision and Control, 2002..

[14]  M. Baotic,et al.  An efficient algorithm for computing the state feedback optimal control law for discrete time hybrid systems , 2003, Proceedings of the 2003 American Control Conference, 2003..

[15]  Alberto Bemporad,et al.  Efficient conversion of mixed logical dynamical systems into an equivalent piecewise affine form , 2004, IEEE Transactions on Automatic Control.

[16]  Alberto Bemporad,et al.  HYSDEL-a tool for generating computational hybrid models for analysis and synthesis problems , 2004, IEEE Transactions on Control Systems Technology.

[17]  Alberto Bemporad,et al.  Dynamic programming for constrained optimal control of discrete-time linear hybrid systems , 2005, Autom..

[18]  H.E. Tseng,et al.  Hybrid Model Predictive Control Application Towards Optimal Semi-Active Suspension , 2005, Proceedings of the IEEE International Symposium on Industrial Electronics, 2005. ISIE 2005..