Experimental and Numerical Validation of a Reliable Sliding Mode Control Strategy Considering Uncertainty with Interval Arithmetic

Real applications are often affected by uncertainty caused by, for example, unknown parameters, sensor inaccuracies, and noise processes. These effects influence control procedures in a significant way and have to be taken into consideration in simulations and experiments to ensure stability of a real system. Often, the dynamics of a considered system can be described by nonlinear equations. To control such systems, sliding mode techniques are advantageous in compensating not explicitly modeled disturbances that influence a system. In this contribution, common sliding mode controllers are extended and combined with interval arithmetic to enhance their performance. This can be achieved by an adaptive calculation of the state-dependent gain stabilizing the variable-structure part of the system—the so-called switching amplitude. Therefore, an exact knowledge of the system parameters is not necessary because their true values are assumed to be located in specified range bounds. Moreover, stochastic uncertainty is taken into consideration representing process and measurement noise that affect practically every real system.

[1]  Andreas Rauh,et al.  Experimental parameter identification for a control-oriented model of the thermal behavior of high-temperature fuel cells , 2011, 2011 16th International Conference on Methods & Models in Automation & Robotics.

[2]  Luc Jaulin,et al.  Applied Interval Analysis , 2001, Springer London.

[3]  Andreas Rauh,et al.  Robust Sliding Mode Techniques for Control and State Estimation of Dynamic Systems with Bounded and Stochastic Uncertainty , 2014 .

[4]  Jon G. Rokne,et al.  Interval Arithmetic , 1992, Graphics Gems III.

[5]  Andreas Rauh,et al.  Sliding Mode Techniques for Robust Trajectory Tracking as well as State and Parameter Estimation , 2014, Math. Comput. Sci..

[6]  Andreas Rauh,et al.  Sliding Mode Approaches Considering Uncertainty for Reliable Control and Computation of Confidence Regions in State and Parameter Estimation , 2014, SCAN.

[7]  H. Marquez Nonlinear Control Systems: Analysis and Design , 2003, IEEE Transactions on Automatic Control.

[8]  H. Kushner Stochastic Stability and Control , 2012 .

[9]  Andreas Rauh,et al.  Optimal input design for online state and parameter estimation using interval sliding mode observers , 2013, 52nd IEEE Conference on Decision and Control.

[10]  Andreas Rauh,et al.  Interval Methods for Robust Sliding Mode Control Synthesis of High-Temperature Fuel Cells with State and Input Constraints , 2016 .

[11]  Andreas Rauh,et al.  Reliable control of high-temperature fuel cell systems using interval-based sliding mode techniques , 2016, IMA J. Math. Control. Inf..

[12]  Daniel Boley,et al.  Numerical Methods for Linear Control Systems , 1994 .

[13]  A. Bartoszewicz,et al.  Time-Varying Sliding Modes for Second and Third Order Systems , 2009 .

[14]  Andreas Rauh,et al.  Sensitivity-Based State and Parameter Estimation for Fuel Cell Systems , 2012, ROCOND.

[15]  Andreas Rauh,et al.  Uses of GPU Powered Interval Optimization for Parameter Identification in the Context of SO Fuel Cells , 2013, NOLCOS.

[16]  Eduardo D. Sontag,et al.  Mathematical Control Theory: Deterministic Finite Dimensional Systems , 1990 .

[17]  Stephen P. Boyd,et al.  Linear Matrix Inequalities in Systems and Control Theory , 1994 .

[18]  Andreas Rauh,et al.  Interval-based sliding mode control and state estimation for uncertain systems , 2012, 2012 17th International Conference on Methods & Models in Automation & Robotics (MMAR).