Efficient Computation of a Guaranteed Lower Bound on
the Robust Stability Margin for a Class of Uncertain
Systems
Efficient Computation of a Guaranteed Lower Bound on
the Robust Stability Margin for a Class of Uncertain
Systems
V. Balakrishnan and F. Wang
In Proc. IEEE Conference on Decision and Control,
pages 4406-4407,
Tampa, Florida, December 1998
Abstract:
Sufficient conditions for the robust
stability of uncertain systems, with several
different assumptions on the structure and nature of the
uncertainties, can be derived in a unified manner in the
framework of integral quadratic constraints. These
sufficient conditions, in turn, can be used to derive
lower bounds on the robust stability margin for such
systems. The lower bounds are typically computed with a
bisection scheme, with each iteration requiring the
solution of a linear matrix inequality feasibility
problem. We show how this bisection can be avoided
altogether by reformulating the lower bound computation
problems as generalized eigenvalue minimization
problems, which can be solved very efficiently using
standard algorithms. Our approach can be applied to many
important, commonly-encountered special cases: Diagonal,
nonlinear uncertainties; diagonal, memoryless,
time-invariant sector-bounded (``Popov'') uncertainties;
structured dynamic uncertainties; and structured
parametric uncertainties. We also illustrate, using a
numerical example, the computational savings that can be
obtained with our approach.
Download Postscript
PDF
Bibtex entry