Title :
Subspace identification with guaranteed stability using constrained optimization
Author :
Lacy, Seth L. ; Bernstein, Dennis S.
Author_Institution :
Space Vehicles Directorate, Air Force Res. Lab., Kirtland AFB, NM, USA
fDate :
7/1/2003 12:00:00 AM
Abstract :
In system identification, the true system is often known to be stable. However, due to finite sample constraints, modeling errors, plant disturbances and measurement noise, the identified model may be unstable. We present a constrained optimization method to ensure asymptotic stability of the identified model in the context of subspace identification methods. In subspace identification, we first obtain an estimate of the state sequence or extended observability matrix and then solve a least squares optimization problem to estimate the system parameters. To ensure asymptotic stability of the identified model, we write the least-squares optimization problem as a convex linear programming problem with mixed equality, quadratic, and positive-semidefinite constraints suitable for existing convex optimization codes such as SeDuMi. We present examples to illustrate the method and compare to existing approaches.
Keywords :
constraint theory; convex programming; least squares approximations; linear programming; matrix algebra; noise; observability; optimisation; stability criteria; state estimation; SeDuMi; asymptotic stability; constrained optimization; convex linear programming problem; convex optimization codes; extended observability matrix estimation; finite sample constraints; guaranteed stability; least squares optimization problem; least-squares optimization problem; measurement noise; mixed equality constraints; modeling errors; plant disturbances; positive-semidefinite constraints; quadratic constraints; state sequence estimation; subspace identification; Asymptotic stability; Constraint optimization; Context modeling; Least squares approximation; Noise measurement; Observability; Optimization methods; State estimation; Subspace constraints; System identification;
Journal_Title :
Automatic Control, IEEE Transactions on
DOI :
10.1109/TAC.2003.814273
