Stabilization of Nonholonomic Systems                      219

                              the large has been advocated in several papers, and typically in the context
                              of stabilization of unstable equilibria of mechanical systems. However, what
                              makes the present result interesting is that we aim at achieving robust asymptotic
                              stability rather than asymptotic stability.


                              5.8 ROBUST STABILITAZION —PART III
                              In the aforementioned discussion, we have implicitly assumed that the control
                              signals are continuous, that is, are generated by an analog device, and measure-
                              ment signals are also continuous. In real applications, however, control signals
                              are (in general) computed by a digital device, and measurements are obtained
                              by sample and hold of physical signals. This implies that, from a realistic point
                              of view, it is necessary to regard the system to be controlled as a sampled-data
                              system. Control of nonlinear sampled-data systems has recently gained a lot
                              of interest, see for example, References 40 and 62. The main issue in address-
                              ing and solving sampled-data control problems for nonlinear systems is the
                              definition of an adequate discrete time model, which should describe (with a
                              given accuracy) the behavior of the sampled-data system. This problem has been
                              widely addressed in the numerical analysis literature, see References 40 and 41.
                              In particular, it has been shown that approximate discrete time models obtained
                              using standard Euler approximation are adequate for control, provided that one
                              is ready to trade global properties with semi-global properties and asymptotic
                              properties with practical properties.

                              5.8.1 Robust Sampled-Data Control of Power Systems

                              In this section we focus on systems in power form (see Equation (5.23)) and on
                              their Euler approximate discrete time model given by

                                    x 1 (k + 1) = x 1 (k) + Tu 1 (k) + d 1 (x(k), k)
                                    x 2 (k + 1) = x 2 (k) + Tu 2 (k) + d 2 (x(k), k)

                                    x 3 (k + 1) = x 3 (k) + Tx 1 (k)u 2 (k) + d 3 (x(k), k)
                                                                                       (5.36)
                                           .
                                           .
                                           .
                                                        1     (n−2)
                                    x n (k + 1) = x n (k) +  Tx 1  u 2 (k) + d n (x(k), k)
                                                     (n − 2)!
                                                                                    n
                              where we have also included the additive disturbance d(x(k), k) ∈ R .
                              Theorem 5.8  [42] Consider the Euler approximate model in Equation (5.36)
                                                                    b
                              with d(x(k), k) = 0 for all k. Let ρ(s) = g 0 |s| with b > 0 and g 0 > 0 and



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                                 FRANKL: “dk6033_c005” — 2006/3/31 — 16:42 — page 219 — #33